977 108 76MB
English Pages 1664 [1666] Year 2011
AUTOMOTIVE TECHNOLOGY Principles, Diagnosis, and Service F O U R T H
E D I T I O N
James D. Halderman
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ISBN-10: 0-13-254261-7 ISBN-13: 978-0-13-254261-6
PREFACE UPDATES TO THE FOURTH EDITION
Number of chapters increased from 103 to 130.
Many long chapters were split and content was reorganized to make teaching and learning easier.
New chapters include: Chapter 17 – Preventive Maintenance and Service Procedures Chapter 19 – Diesel Engine Operation and Diagnosis Chapter 20 – Coolant Chapter 22 – Engine Oil Chapter 27 – In-Vehicle Engine Service Chapter 36 – Gaskets and Sealants Chapter 37 – Engine Assembly and Dynamometer Testing Chapter 49 – CAN and Network Communications Chapter 66 – Gasoline Chapter 67 – Alternative Fuels Chapter 68 – Diesel and Biodiesel Fuels Chapter 79 – Gasoline Direct Injection Systems Chapter 80 – Electronic Throttle Control Systems Chapter 108 – Electronic Stability Control Systems Chapter 110 – Tire Pressure Monitoring Systems
ASE AND NATEF CORRELATED
This comprehensive textbook is divided into sections that correspond to the eight areas of certifications as specified by the National Institute for Automotive Service Excellence (ASE) and the National Automotive Technicians Education Foundation (NATEF). The areas of the ASE material certification test are listed in the objectives at the beginning of each chapter, and all laboratory worksheets are correlated to the NATEF Task List.
A COMPLETE INSTRUCTOR AND STUDENT SUPPLEMENT PACKAGE This book is accompanied by a full set of instructor and student supplements. Please see page v for a detailed list of supplements.
A FOCUS ON DIAGNOSIS AND PROBLEM SOLVING The primary focus of this textbook is to satisfy the need for problem diagnosis. Time and again, the author has heard that technicians need more training in diagnostic procedures and skill development. To meet this need and to help illustrate how real problems are solved, diagnostic stories are included throughout. Each new topic covers the parts involved as well as their purpose, function, and operation, and how to test and diagnose each system. The following pages highlight the unique core features that set this book apart from other automotive textbooks.
Chapter 115 – Electronic Suspension Systems Chapter 127 – Automatic Transmission/Transaxle Principles Chapter 128 – Hydraulic Components and Control Systems Chapter 129 – Automatic Transmission/Transaxle Diagnosis and In-Vehicle Service Chapter 130 – Automatic Transmission/Transaxle Unit Repair
Over 300 new color photos and line drawings.
New design, showing major and minor headings, is clearer and makes it easier to grasp important information.
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IN-TEXT FEATURES
S E C T I O N
REAL WORLD FIX
Careers in the Automotive Service Area
I
Lightning Damage 1
Automotive Background and Overview
4
Working as a Professional Service Technician
2
Careers in the Automotive Service Industry
5
Technician Certification
3
Starting a Career in the Automotive Industry
chapter
AUTOMOTIVE BACKGROUND AND OVERVIEW
1
OBJECTIVES: After studying Chapter 1, the reader will be able to: • Explain the evolution of the automobile. • Discuss the major components of a vehicle. • Describe the evolution of engines. • List the common components of most vehicles. • List the eight areas of automotive service according to ASE/NATEF. KEY TERMS: Air filter 5 • Body 2 • Body-on-frame (BOF) 3 • Carbon monoxide (CO) 5 • Catalytic converter 5 • Chassis 2 • Coolant 5 • Drive shaft 5 • Double overhead camshaft (DOHC) 4 • Evaporative emission system (EVAP) 5 • Exhaust gas recirculation (EGR) 5 • Flathead 4 • Frames 3 • Hydrocarbon (HC) 5 • Ignition control module (ICM) 5 • Inline engine 4 • Intake manifold 5 • Internal combustion engine 4 • Malfunction indicator lamp (MIL) 5 • Manufacturer’s suggested retail price (MSRP) 4 • OBD-II 5 • Oil filter 5 • Oil galleries 5 • Oil pan 5 • Oil pump 5 • Oil sump 5 • Overhead camshaft (OHC) 4 • Overhead valve (OHV) 4 • Oxides of nitrogen (NOX) 5 • PCV valve 5 • Pillars 3 • Positive crankcase ventilation (PCV) 5 • Propeller shaft 5 • Radiator 5 • Scan tool 5 • Self-propelled vehicle 1 • Single overhead camshaft (SOHC) 4 • Thermostat 5 • Transaxle 6 • Transfer case 6 • Unibody 3 • Universal joints (U-joints) 5 • Water jackets 5 • Water pump 5
1896
Henry Ford (1863–1947) built his first car, called the Quadricycle. SEE FIGURE 1–1.
1900
About 4,200 total automobiles were sold, including:
HISTORICAL BACKGROUND For centuries, man either walked or used animals to provide power for transportation. After the invention of electric, steam, and gasoline propulsion systems, people used self-propelled vehicles, which are vehicles that moved under their own power. Major milestones in vehicle development include: 1876
The OTTO four-stroke cycle engine was developed by a German engineer, Nikolaus Otto.
1885
The first automobile was powered by an OTTO cycle gasoline engine designed by Karl Friedrick Beary (1844–1929).
1892
Rudolf Diesel (1858–1913) received a patent for a compression ignition engine. The first diesel engine was built in 1897.
REAL WORLD FIXES present students with actual automotive service scenarios and show how these common (and sometimes uncommon) problems were diagnosed and repaired.
• 40% were steam powered • 38% were battery/electric powered • 22% were gasoline engine powered 1902
Oldsmobile, founded by Ransom E. Olds (1864–1950), produced the first large-scale, affordable vehicle.
1908
William Durant (1861–1947) formed General Motors.
1908
The Ford Model T was introduced.
AUTOMOTIVE BACKGROUND AND OVERVIEW
A radio failed to work in a vehicle that was outside during a thunderstorm. The technician checked the fuses and verified that power was reaching the radio. Then the technician noticed the antenna. It had been struck by lightning. Obviously, the high voltage from the lightning strike traveled to the radio receiver and damaged the circuits. Both the radio and the antenna were replaced to correct the problem. SEE FIGURE 26–26.
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OBJECTIVES AND KEY TERMS
appear at the beginning of each chapter to help students and instructors focus on the most important material in each chapter. The chapter objectives are based on specific ASE and NATEF tasks.
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FREQUENTLY ASKED QUESTION
What Is an “SST?” Vehicle manufacturers often specify a special service tool (SST) to properly disassemble and assemble components, such as transmissions and other components. These tools are also called special tools and are available from the vehicle manufacturer or their tool supplier, such as Kent-Moore and Miller tools.
TECH TIP Right to TIghten Whenever removing any automotive component, it is wise to screw the bolts back into the holes a couple of threads by hand. This ensures that the right bolt will be used in its original location.
FREQUENTLY ASKED QUESTIONS are based on the author’s own experience and provide answers to many of the most common questions asked by students and beginning service technicians.
NOTE:
Most of these “locking nuts” are grouped together
and are commonly referred to as revailing torque nuts. This
TECH TIP
feature real-world advice and “tricks of the trade” from ASE-certified master technicians.
means that the nut will hold its tightness or torque and not loosen with movement or vibration.
NOTES
provide students with additional technical information to give them a greater understanding of a specific task or procedure.
SAFETY TIP Shop Cloth Disposal Always dispose of oily shop cloths in an enclosed container to prevent a fire. SEE FIGURE 1–69. Whenever oily cloths are thrown together on the floor or workbench, a chemical reaction can occur, which can ignite the cloth even without an open flame. This process of ignition without an open flame is called spontaneous combustion.
SAFETY TIPS
alert students to possible hazards on the job and how to avoid them.
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P REFACE
CAUTION: Never use hardware store (nongraded) bolts, studs, or nuts on any vehicle steering, suspension, or brake component. Always use the exact size and grade of hardware that is specified and used by the vehicle manufacturer.
CAUTIONS
alert students about potential damage to the vehicle that can occur during a specific task or service procedure.
WARNING REVIEW QUESTIONS 1. What are the typical operations needed when disassembling an automatic transmission/transaxle?
Do not use incandescent trouble lights around gasoline or other flammable liquids. The liquids can cause the bulb to break and the hot filament can ignite the flammable liquid which can cause personal injury or even death.
2. What are two methods of checking a clutch pack?
CHAPTER QUIZ
WARNINGS
alert students to potential dangers to themselves during a specific task or service procedure.
TRANSAXLE REMOVAL
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For safety purposes, remove the negative battery cable before starting the removal procedure.
Remove engine bay cross members that may interfere with access to the transaxle fasteners.
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Disconnect the lower ball joint on the front-wheel-drive vehicle to allow removal of the drive axle shaft.
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1. Technician A says that the torque converter should be separated from the flex (drive) plate before removing the automatic transmission/transaxle. Technician B says that the clutches should be installed “dry” when replacing the frictions and steels in a clutch pack. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
6. Technician A says that the sharp edges of spool valves should be rounded, using 400 grit sandpaper. Technician B says that all valve body parts should be cleaned and then dried using low-pressure, filtered compressed air. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
2. Air pressure checking is used to test ______________. a. Clutch packs b. TV adjustment c. Vacuum modulators d. Governors
7. Clutch pack clearance can be changed if not correct by using selective ______________. a. Piston b. Pressure plate c. Snap ring d. One of the above depending on the unit
3. Technician A says that all friction and steel plates in a clutch pack should be replaced during an overhaul. Technician B says that the automatic transmission fluid cooler should always be flushed when a unit is rebuilt or replaced. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
STEP BY STEP
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4. Slide hammers or special pullers are used to remove what component? a. Extension housing b. Filter c. Pump d. Rear seal
Remove the drive axle shaft from the transaxle using a pry bar.
5. What part must be replaced if dropped? a. Pump b. Torque converter c. Extension housing d. Pan
3
Remove the air intake and air filter assembly, which is covering the transaxle in this vehicle.
4
Install a support for the engine.
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Safely hoist the vehicle and remove the wheels.
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Remove the retaining nut from the drive axle shaft.
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Disconnect the cooler lines from the transaxle using a line wrench.
11
With the transaxle supported on a transmission jack, remove the retaining bolts from the bell housing.
C H APTE R 130
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Unbolt the torque converter from the flexplate, then remove the transaxle mounts.
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Carefully remove the transaxle from the vehicle.
AU TOM ATI C TR AN SM I SSI ON /TRAN SAX L E U N I T R E PAI R
4. Why is it important to flush the automatic transmission fluid cooler when a rebuilt or replacement automatic transmission/ transaxle is being installed in a vehicle?
3. Why is it important to perform an end play check of an automatic transmission/transaxle during the reassembly process?
8. Friction discs should be ______________before being installed. a. Sanded b. Soaked in ATF c. Surface roughed up d. All of the above 9. How much transmission fluid should flow through the cooler? a. 2 quarts every 30 seconds b. 1 quart per minute c. 2 quarts per minute d. 2 pints per minute 10. Why should red assembly lube be avoided? a. Can harm friction disks b. Too slippery c. Clogs filters d. Looks like an ATF leak when it melts
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STEP-BY-STEP photo sequences show in detail the steps involved in performing a specific task or service procedure.
CHAPTER 130
THE REVIEW QUESTIONS AND CHAPTER QUIZ
at the end of each chapter help students review the material presented in the chapter and test themselves to see how much they’ve learned.
SUPPLEMENTS INSTRUCTOR SUPPLEMENTS
The instructor supplement package has been completely revamped to reflect the needs of today’s instructors. The Annotated Instructor’s Guide (ISBN: 0-13-255157-8) is the cornerstone of the package and includes:
Chapter openers that list:
— Safety Tips — Classroom discussion questions
Also included in the instructor supplement package are:
— NATEF/ASE tasks covered in the chapter
PowerPoint presentations
— All key terms
Image Library containing every image in the book for use in class or customized PowerPoints
TestGen software and test bank
— All chapter objectives
A guide to using MyAutomotiveLab in the course
The entire text (matching page numbers with student edition) with margin notes. These notes include:
Chapter Quizzes
— Tips for in-class demonstrations
Chapter Review Questions
— Suggested hands-on activities
English and Spanish glossary
— Cross-curricular activities
NATEF Correlated Task Sheets
— Internet search tips
NATEF/ASE Correlation Charts
— Assessments
P REF A C E
v
SUPPLEMENTS (CONTINUED) To access supplementary materials online, instructors need to request an instructor access code. Go to www.pearsonhighered.com/ irc to register for an instructor access code. Within 48 hours of registering, you will receive a confirming e-mail including an instructor access code. Once you have received your code, locate your text in the online catalog and click on the Instructor Resources button on the left side of the catalog product page. Select a supplement, and a login page will appear. Once you have logged in, you can access instructor material for all Prentice Hall textbooks. If you have any difficulties accessing the site or downloading a supplement, please contact Customer Service at http://247.prenhall.com.
STUDENT SUPPLEMENTS Today’s student has more access to the Internet than ever, so all supplemental materials are downloadable at the following site for no additional charge: www. pearsoned.com/autostudent On the site, students will find:
PowerPoint presentations
Chapter review questions and quizzes
English and Spanish glossary
A full Spanish translation of the text
ACKNOWLEDGMENTS A large number of organizations have cooperated in providing the reference material and technical information used in this text. The author wishes to express sincere thanks to the following organizations for their special contributions: Accu Industries, Inc Allied Signal Automotive Aftermarket Arrow Automotive ASE Automotion, Inc Automotive Engine Rebuilders Association (AERA) Automotive Parts Rebuilders Association (APRA) Automatic Transmission Rebuilders Association (ATRA) Battery Council International (BCI) Chrysler Corporation Clayton Associates Cooper Automotive Company Dana Corporation, Perfect Circle Products Defiance Engine Rebuilders, Incorporated Delphi Chassis, GMC The Dow Chemical Company Duralcan USA EIS Brake Parts Envirotest Systems Corporation Fel-Pro Incorporated Fluke Corporation FMSI Ford Motor Company General Electric Lighting Division General Motors Corporation Service Technology Group Goodson Auto Machine Shop Tools and Supplies Greenlee Brothers and Company Hennessy Industries Hunter Engineering Company Jasper Engines and Transmissions John Bean Company Modine Manufacturing Company Neway Northstar Manufacturing Company, Inc. Parsons and Meyers Racing Engines Perfect Hofmann-USA Raybestos Brake Parts, Inc.
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PREFACE
Reynolds and Reynolds Company Robert Bosch Corporation Rottler Manufacturing Shimco International, Inc. SKF USA, Inc. SnapOn Tools Society of Automotive Engineers (SAE) Specialty Productions Company Sunnen Products Company Toyota Motor Sales, USA, Inc. TRW Inc. Wurth USA, Inc. The author would also like to thank the following individuals for their help. Dan Avery Tom Birch Randy Dillman Rick Escalambre, Skyline College Bill Fulton, Ohio Automotive Technology Jim Linder, Linder Technical Services, Inc. Scot Manna Dan Marinucci, Communique’ Jim Morton, Automotive Training center (ATC) Dr. Norman Nall Dave Scaler, Mechanic’s Education Association John Thornton, Autotrain Mark Warren Mike Watson, Watson Automotive LLC
TECHNICAL AND CONTENT REVIEWERS
The following people reviewed the manuscript before production and checked it for technical accuracy and clarity of presentation. Their suggestions and recommendations were included in the final draft of the manuscript. Their input helped make this textbook clear and technically accurate while maintaining the easy-to-read style that has made other books from the same author so popular. Jim Anderson Greenville High School Rankin E. Barnes Guilford Technical Community College
ACKNOWLEDGMENTS (CONTINUED) Victor Bridges Umpqua Community College
Dennis Peter NAIT (Canada)
Darrell Deeter Saddleback College
Kenneth Redick Hudson Valley Community College
Matt Dixon Southern Illinois University
Matt Roda Mott Community College
Dr. Roger Donovan Illinois Central College
Omar Trinidad Southern Illinois University
A. C. Durdin Moraine Park Technical College
Mitchell Walker St. Louis Community College at Forest Park
Herbert Ellinger Western Michigan University
Thanks to the myautomotivelab advisory board and contributors.
Al Engledahl College of DuPage
Chris Tran San Jacinto College
Robert M. Frantz Ivy Tech Community College, Richmond
Homer Swihart San Jacinto College
Christopher Fry Harry S. Truman College
Craig Robinson Broward College
Larry Hagelberger Upper Valley Joint Vocational School
Eric Erskin Ivy Tech Community College
Oldrick Hajzler Red River College
Robert Huettl Ivy Tech Community College
Gary F. Ham South Plains College
Al Gentles Ranken Technical College
Betsy Hoffman Vermont Technical College
Steve Quinn Olympic College
Marty Kamimoto Fresno City College
Contributors:
Richard Krieger Michigan Institute of Technology Steven T. Lee Lincoln Technical Institute Carlton H. Mabe, Sr. Virginia Western Community College Roy Marks Owens Community College Tony Martin University of Alaska Southeast Kerry Meier San Juan College Clifford G. Meyer Saddleback College Kevin Murphy Stark State College of Technology Fritz Peacock Indiana Vocational Technical College
David W. Foor Columbus State Community College Kevin Ruby Chattahoochee Technical College John Gardner Chipola College Dennis A. Iudice KDI Automotive University William T. Reny Transportation Component Solutions, LLC
SPECIAL THANKS I also wish to thank Chuck Taylor, Blaine Heeter, and Mike Garblik from Sinclair Community College in Dayton, Ohio, for their help with many of the photo sequences. A special thanks to Dick Krieger for his detailed and thorough reviews of the manuscript before publication. Most of all, I want to thank my wife, Michelle Halderman, for her help in all phases of manuscript preparation. —James D. Halderman
P REF A C E
vii
ABOUT THE AUTHOR JIM HALDERMAN brings a world of experience, knowledge, and talent to his work. His automotive service experience includes working as a flat-rate technician, a business owner, and a professor of automotive technology at a leading U.S. community college for more than 20 years. He has a Bachelor of Science Degree from Ohio Northern University and a Masters Degree in Education from Miami University in Oxford, Ohio. Jim also holds a U.S. Patent for an electronic transmission control device. He is an ASE certified Master Automotive Technician and Advanced Engine Performance (L1) ASE certified. Jim is the author of many automotive textbooks all published by Pearson Prentice Hall Publishing Company. Jim has presented numerous technical seminars to national audiences including the California Automotive Teachers (CAT) and the Illinois College Automotive Instructor Association (ICAIA) as well as a member and presenter at the North American Council of Automotive Teachers (NACAT). Jim was also named Regional Teacher of the Year by General Motors Corporation and outstanding alumni of Ohio Northern University. Jim and his wife, Michelle, live in Dayton, Ohio. They have two children.
[email protected]
viii
ABOUT THE AUTHOR
BRIEF CONTENTS SECTION I
Careers in the Automotive Service Area 1
chapter 1
Automotive Background and Overview
chapter 2
Careers in the Automotive Service Industry
chapter 3
Starting a Career in the Automotive Industry
chapter 4
Working as a Professional Service Technician
chapter 5
Technician Certification
SECTION II
Safety, Environmental, and Health Concerns 41
chapter 6
Shop Safety
chapter 7
Environmental and Hazardous Materials
SECTION III
Tools, Shop Equipment, and Measuring 57
chapter 8
Fasteners and Thread Repair
chapter 9
Hand Tools
chapter 10
Power Tools and Shop Equipment
chapter 11
Vehicle Lifting and Hoisting
chapter 12
Measuring Systems and Tools
SECTION IV
Principles, Math, and Calculations 105
chapter 13
Scientific Principles and Materials
chapter 14
Math, Charts, and Calculations
SECTION V
Vehicle Service Information, Identification, and Routine Maintenance 119
chapter 15
Service Information
chapter 16
Vehicle Identification and Emission Ratings
chapter 17
Preventative Maintenance and Service Procedures
SECTION VI
Engine Repair 146
chapter 18
Gasoline Engine Operation, Parts, and Specifications
chapter 19
Diesel Engine Operation and Diagnosis
chapter 20
Coolant
chapter 21
Cooling System Operation and Diagnosis
chapter 22
Engine Oil
chapter 23
Lubrication System Operation and Diagnosis
chapter 24
Intake and Exhaust Systems
chapter 25
Turbocharging and Supercharging
chapter 26
Engine Condition Diagnosis
chapter 27
In-Vehicle Engine Service
chapter 28
Engine Removal and Disassembly
1 8 16 24
34
41 48
57
68 82
91 97
105
114
119 125 130
146
158
175 182
198 210
219 227
237 252 261
BRIEF C ON T EN T S
ix
chapter 29
Engine Cleaning and Crack Detection
272
chapter 30
Cylinder Head and Valve Guide Service
chapter 31
Valve and Seat Service
chapter 32
Camshafts and Valve Trains
chapter 33
Pistons, Rings, and Connecting Rods
chapter 34
Engine Blocks
chapter 35
Crankshafts, Balance Shafts, and Bearings
chapter 36
Gaskets and Sealants
chapter 37
Engine Assembly and Dynamometer Testing
chapter 38
Engine Installation and Break-in
SECTION VII
Electrical and Electronic Systems 420
chapter 39
Electrical Fundamentals
chapter 40
Electrical Circuits and Ohm’s Law
chapter 41
Series, Parallel, and Series-Parallel Circuits
chapter 42
Circuit Testers and Digital Meters
chapter 43
Oscilloscopes and Graphing Multimeters
chapter 44
Automotive Wiring and Wire Repair
chapter 45
Wiring Schematics and Circuit Testing
chapter 46
Capacitance and Capacitors
chapter 47
Magnetism and Electromagnetism
chapter 48
Electronic Fundamentals
chapter 49
CAN and Network Communications
chapter 50
Batteries
chapter 51
Battery Testing and Service
chapter 52
Cranking System
chapter 53
Cranking System Diagnosis and Service
chapter 54
Charging System
chapter 55
Charging System Diagnosis and Service
chapter 56
Lighting and Signaling Circuits
chapter 57
Driver Information and Navigation Systems
chapter 58
Horn, Wiper, and Blower Motor Circuits
chapter 59
Accessory Circuits
chapter 60
Airbags and Pretensioner Circuits
chapter 61
Audio System Operation and Diagnosis
280
293 314 336
351 364
381 388
415
420 428 434
444 460
467 479
493 498
509 524
538 544
556 566
577 587
604 625
646
657 686 698
SECTION VIII Heating and Air Conditioning 712
x
chapter 62
Heating and Air-Conditioning Components and Operation
chapter 63
Automatic Air-Conditioning System Operation
BRIEF CONTENTS
731
712
chapter 64
Heating and Air-Conditioning System Diagnosis
737
chapter 65
Heating and Air-Conditioning System Service
SECTION IX
Engine Performance 754
chapter 66
Gasoline
chapter 67
Alternative Fuels
chapter 68
Diesel and Biodiesel Fuels
chapter 69
Ignition System Components and Operation
chapter 70
Ignition System Diagnosis and Service
chapter 71
Computer Fundamentals
chapter 72
Temperature Sensors
chapter 73
Throttle Position (TP) Sensors
chapter 74
MAP/BARO Sensors
chapter 75
Mass Air Flow Sensors
chapter 76
Oxygen Sensors
chapter 77
Fuel Pumps, Lines, and Filters
chapter 78
Fuel-Injection Components and Operation
chapter 79
Gasoline Direct-Injection Systems
887
chapter 80
Electronic Throttle Control System
892
chapter 81
Fuel-Injection System Diagnosis and Service
chapter 82
Vehicle Emission Standards and Testing
chapter 83
Evaporative Emission Control Systems
chapter 84
Exhaust Gas Recirculation Systems
chapter 85
Positive Crankcase Ventilation and Secondary Air-Injection Systems 942
chapter 86
Catalytic Converters
chapter 87
OnBoard Diagnosis
chapter 88
Scan Tools and Engine Performance Diagnosis
SECTION X
Hybrid and Fuel Cell Vehicles 983
chapter 89
Introduction to Hybrid Vehicles
chapter 90
Hybrid Safety and Service Procedures
chapter 91
Fuel Cells and Advanced Technologies
SECTION XI
Brakes
chapter 92
Braking System Components and Performance Standards
chapter 93
Braking System Principles
chapter 94
Brake Hydraulic Systems
chapter 95
Hydraulic Valves and Switches
chapter 96
Brake Fluid and Lines
chapter 97
Brake Bleeding Methods and Procedures
745
754 766 777 781
794
812
819 828
832 840
845 860 875
900
918 927
935
948 957 965
983 991 1002
1015 1015
1021 1027 1040
1050 1061
BRIEF C ON T EN T S
xi
chapter 98
Wheel Bearings and Service
1070
chapter 99
Drum Brakes
chapter 100
Drum Brake Diagnosis and Service
chapter 101
Disc Brakes
chapter 102
Disc Brakes Diagnosis and Service
chapter 103
Parking Brake Operation, Diagnosis, and Service
chapter 104
Machining Brake Drums and Rotors
chapter 105
Power Brake Unit Operation, Diagnosis, and Service
chapter 106
ABS Components and Operation
chapter 107
ABS Diagnosis and Service
chapter 108
Electronic Stability Control Systems
SECTION XII
Suspension and Steering 1239
chapter 109
Tires and Wheels
chapter 110
Tire Pressure Monitoring Systems
chapter 111
Tire and Wheel Service
chapter 112
Suspension System Principles and Components
chapter 113
Front Suspensions and Service
1311
chapter 114
Rear Suspensions and Service
1335
chapter 115
Electronic Suspension Systems
chapter 116
Steering Columns and Gears
1358
chapter 117
Steering Linkage and Service
1372
chapter 118
Power-Assisted Steering Operation and Service
chapter 119
Wheel Alignment Principles
chapter 120
Alignment Diagnosis and Service
1087 1101
1114 1128 1145
1157 1195
1208
1220 1232
1239 1261
1270 1288
1343
1388
1413 1427
SECTION XIII Manual Drive train and Axles 1454 chapter 121
Clutches
1454
chapter 122
Manual Transmissions/Transaxles
chapter 123
Drive Axle Shafts and CV Joints
chapter 124
Drive Axle Shafts and CV Joint Service
chapter 125
Differentials
chapter 126
Four-Wheel-Drive and All-Wheel Drive
1471 1494 1503
1516 1534
SECTION XIV Automatic Transmissions and Transaxles 1551 chapter 127
Automatic Transmission/Transaxle Principles
1551
chapter 128
Hydraulic Components and Control Systems
1567
chapter 129
Automatic Transmission/Transaxle Diagnosis and In-Vehicle Service
chapter 130
Automatic Transmission/Transaxle Unit Repair Index
xii
BRIEF CONTENTS
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1598
1586
S E C T I O N
I
Careers in the Automotive Service Area
1
Automotive Background and Overview
4
Working as a Professional Service Technician
2
Careers in the Automotive Service Industry
5
Technician Certification
3
Starting a Career in the Automotive Industry
chapter
1
AUTOMOTIVE BACKGROUND AND OVERVIEW
OBJECTIVES: After studying Chapter 1, the reader will be able to: • Explain the evolution of the automobile. • Discuss the major components of a vehicle. • Describe the evolution of engines. • List the common components of most vehicles. • List the eight areas of automotive service according to ASE/NATEF. KEY TERMS: Air filter 5 • Body 2 • Body-on-frame (BOF) 3 • Carbon monoxide (CO) 5 • Catalytic converter 5 • Chassis 2 • Coolant 5 • Drive shaft 5 • Double overhead camshaft (DOHC) 4 • Evaporative emission system (EVAP) 5 • Exhaust gas recirculation (EGR) 5 • Flathead 4 • Frames 3 • Hydrocarbon (HC) 5 • Ignition control module (ICM) 5 • Inline engine 4 • Intake manifold 5 • Internal combustion engine 4 • Malfunction indicator lamp (MIL) 5 • Manufacturer’s suggested retail price (MSRP) 4 • OBD-II 5 • Oil filter 5 • Oil galleries 5 • Oil pan 5 • Oil pump 5 • Oil sump 5 • Overhead camshaft (OHC) 4 • Overhead valve (OHV) 4 • Oxides of nitrogen (NOX) 5 • PCV valve 5 • Pillars 3 • Positive crankcase ventilation (PCV) 5 • Propeller shaft 5 • Radiator 5 • Scan tool 5 • Self-propelled vehicle 1 • Single overhead camshaft (SOHC) 4 • Thermostat 5 • Transaxle 6 • Transfer case 6 • Unibody 3 • Universal joints (U-joints) 5 • Water jackets 5 • Water pump 5
1896
Henry Ford (1863–1947) built his first car, called the Quadricycle. SEE FIGURE 1–1.
1900
About 4,200 total automobiles were sold, including:
HISTORICAL BACKGROUND For centuries, man either walked or used animals to provide power for transportation. After the invention of electric, steam, and gasoline propulsion systems, people used self-propelled vehicles, which are vehicles that moved under their own power. Major milestones in vehicle development include: 1876
The OTTO four-stroke cycle engine was developed by a German engineer, Nikolaus Otto.
1885
The first automobile was powered by an OTTO cycle gasoline engine designed by Karl Friedrick Beary (1844–1929).
1892
Rudolf Diesel (1858–1913) received a patent for a compression ignition engine. The first diesel engine was built in 1897.
• 40% were steam powered • 38% were battery/electric powered • 22% were gasoline engine powered 1902
Oldsmobile, founded by Ransom E. Olds (1864–1950), produced the first large-scale, affordable vehicle.
1908
William Durant (1861–1947) formed General Motors.
1908
The Ford Model T was introduced.
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FIGURE 1–1 A Ford Quadricycle built by Henry Ford. 1912
The electric starter was invented by Charles F. Kettering (1876–1958) of Dayton, Ohio, first used on a Cadillac. The starter was produced by a new company called Delco, which stood for Dayton Electric Laboratories Company.
1914
First car with a 100% steel body was made by the Budd Corporation for Dodge. Before 1914, all car bodies had wood components in them.
1922
The first vehicle to have four-wheel hydraulically operated brakes was a Duesenberg built in Indianapolis, Indiana.
1940
The first fully automatic transmission was introduced by Oldsmobile.
1973
Airbags were offered as an option on some General Motors vehicles.
1985
Lincoln offers the first four-wheel antilock braking system.
1997
The first vehicle with electronic stability control was offered by Cadillac.
BODIES Early motor vehicles evolved from horse-drawn carriages. The engine and power train were attached to a modified carriage leading to the term “horseless carriage”. SEE FIGURE 1–2. The bodies evolved until in the 1930s, all-steel-enclosed bodies became the most used type. All bodies depended on a frame of wood or steel to support the chassis components.
CHASSIS SYSTEMS OVERVIEW
FIGURE 1–2 Most vehicle bodies were constructed with a wood framework until the 1920s.
FIGURE 1–3 A chassis of a 1950s era vehicle showing the engine, drivetrain, frame, and suspension. 3. The braking system of the vehicle is used to slow and stop the rotation of the wheels, which in turn stops the vehicle. The braking system includes the brake pedal, master cylinder, plus wheel brakes to each wheel. Two types of wheel brakes are used. Disc brakes include a caliper, which applies force to brake pads on both sides of a rotating disc or rotor. Drum brakes use brake shoes which are applied by hydraulic pressure outward against a rotating brake drum. The brake drum is attached to and stops the rotation of the wheels. Drum brakes are often used on the rear of most vehicles. 4. Wheels and tires—The wheels are attached to the bearing hubs on the axles. The tires must provide traction for accelerating, braking, and cornering, as well as provide a comfortable ride. Wheels are constructed of steel or aluminum alloy and mount to the hubs of the vehicle using lug nuts, which must be tightened correctly to the proper torque. The chassis components include:
The chassis system of the vehicle includes the following components: 1. Frame or body of the vehicle, which is used to provide the support for the suspension and steering components as well as the powertrain. 2. The suspension system of the vehicle, which provides a smooth ride to the driver and passengers and helps the tires remain on the road even when the vehicle is traveling over rough roads. The suspension system includes springs and control arms which allow the wheel to move up and down and keep the tires on the road.
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Front and rear suspension
Axles and hubs (to support the wheels and tires)
Steering mechanism
Engine and transmission
Final drive differential and axles
Often, these chassis were so complete that they could be driven without a body. FIGURE 1–3.
C PILLAR B PILLAR
D PILLAR
WINDSHIELD HEADER A PILLAR COWL HOOD PANEL ONE PIECE GRILLE SOFT COLOR-KEYED BUMPER
SIDE MARKER AND TURNING LAMP
ROCKER PANEL REAR AIR DEFLECTOR WITH INTEGRATED STOP LAMP BACKLIGHT WITH REAR WIPER
REAR VIEW MIRROR INTEGRATED WITH "A" PILLAR AND SIDE GLASS FRONT FENDER
RUNNING TAIL LAMP
BELT LINE
SOFT COLOR-KEYED BUMPER LIFT GATE TAIL LAMP WITH STOP AND TURN FUNCTION QUARTER PANEL
FRONT DOOR REAR DOOR D L O (DAYLIGHT OPENING)
FIGURE 1–4 Body and terms. Many of the expensive automakers in the 1920s and 1930s had bodies built by another company. Eventually, most bodies were constructed of steel and many without the need for a frame to support the drivetrain and suspension.
BODY TERMS The roof of a vehicle is supported by pillars and they are labeled A, B, C, and D from the front to the rear of the vehicle. All vehicles have an A pillar at the windshield but many, such as a hardtop, do not have a B pillar. Station wagons and sport utility vehicles (SUVs) often have a D pillar at the rear of the vehicle. SEE FIGURE 1–4.
FRAMES Frame construction usually consists of channel-shaped steel beams welded and/or fastened together. Vehicles with a separate frame and body are usually called body-on-frame vehicles (BOF). Many terms are used to label or describe the frame of a vehicle including:
FIGURE 1–5 Note the ribbing and the many different pieces of sheet metal used in the construction of this body. TECH TIP
UNIT-BODY CONSTRUCTION
Unit-body construction (sometimes called unibody) is a design that combines the body with the structure of the frame. The body is composed of many individual stamped-steel panels welded together. The strength of this type of construction lies in the shape of the assembly. The typical vehicle uses 300 separate stamped-steel panels that are spot-welded together to form a vehicle’s body. SEE FIGURE 1–5. NOTE: A typical vehicle contains about 10,000 separate individual parts.
Treat a Vehicle Body with Respect Do not sit on a vehicle. The metal can easily be distorted, which could cost hundreds of dollars to repair. This includes sitting on the hood, roof, and deck (trunk) lid, as well as fenders. Also, do not hang on any opened door as this can distort the hinge area causing the door not to close properly.
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FIGURE 1–8 A Monroney label as shown on the side window of a new vehicle. FIGURE 1–6 A Corvette without the body. Notice that the vehicle is complete enough to be driven. This photo was taken at the Corvette Museum in Bowling Green, Kentucky.
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FREQUENTLY ASKED QUESTION
What Is the Monroney Label? The Monroney label is the sticker on the vehicle that lists the manufacturer’s suggested retail price, usually abbreviated MSRP. The law that requires this label on all vehicles is called the Monroney Law, named for the congressman who sponsored the bill, Almer S. Monroney (1902–1980), a U.S. farm representative from Oklahoma from 1939–1951 and a U.S. Senator from 1951 to 1969. Before the Monroney label law was passed in 1958, the price of a vehicle was unknown to new vehicle buyers who had to rely on the dealer for pricing. Besides all of the standard and optional equipment on the vehicle, the Monroney label also includes fuel economy and exhaust emission information. SEE FIGURE 1–8.
FIGURE 1–7 A Ford flathead V-8 engine. This engine design was used by Ford Motor Company from 1932 through 1953. In a flathead design, the valves located next to (beside) the cylinders.
SPACE-FRAME CONSTRUCTION
Space-frame construction consists of formed sheet steel used to construct a framework of the entire vehicle. The vehicle is drivable without the body, which uses plastic or steel panels to cover the steel framework. SEE FIGURE 1–6.
ENGINE DESIGN EVOLUTION All gasoline and diesel engines are called internal combustion engines and were designed to compress an ignitable mixture. This mixture was ignited by using a spark (gasoline) or by heat of compression (diesel). Early engines used valves that were in the engine block, which also contained the round cylinders where pistons were fitted. The pistons are connected to a crankshaft, which converts the up and down motion of the pistons to a rotary force which is used to propel the vehicle.
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INLINE VERSUS V-TYPE DESIGN Most early engines used four or six cylinders arranged inline. These were called inline engines and are still produced today. Some engines with 4, 6, 8, 10, 12, or 16 cylinders were arranged with half of the cylinders on each set of a “V” and connected to a common crankshaft in the bottom of the “V.” The crankshaft changed the up-and-down motion of the piston to rotary motion, allowing the engine to power the drive wheels. VALVE LOCATION DESIGN
The design where the valves were located in the engine block is called flathead design because the cylinder head simply covered the combustion chamber and included a hole for the spark plug. The engine block contains passages for coolant as well as lubricating oil and is the support for all other engine systems. SEE FIGURE 1–7. By the 1950s, most engine designs placed the valves in the cylinder head. This is called an overhead valve or OHV design. Even newer engine designs feature overhead camshafts (OHC), called single overhead camshaft (SOHC) designs and engines that use two overhead camshafts per bank of cylinders called double overhead camshaft (DOHC) designs. The placement of the camshaft, which results in better flow of intake air into and exhaust out of the engine.
The need for reduced emissions and greater fuel economy led to advances in engine design. These changes included:
Electronic ignition systems
Electronic fuel injection
Computerized engine controls
Emission control devices, including the catalytic converter used in the exhaust system to reduce emissions
Improved engine oils that help reduce friction and reduce emissions
ENGINE SYSTEMS OVERVIEW
the electrodes of the spark plug ignites the air-fuel mixture in the combustion chamber and the resulting pressure pushes the piston down on the power stroke.
EMISSION CONTROL SYSTEM
The control of vehicle emissions includes controlling gasoline vapors from being released into the atmosphere in addition to reducing the emissions from the exhaust. Unburned gasoline emissions are called hydrocarbon (HC) emissions and exhaust gases that are controlled include carbon monoxide (CO) and oxides of nitrogen (NOX). The evaporative emission control system, usually called the EVAP system, is designed to prevent gasoline fumes and vapors from being released. Other emission control systems include:
Positive crankcase ventilation (PCV). This system uses a valve called a PCV valve to regulate the flow of gases created in the crankcase of a running engine, which are routed back into the intake manifold. The engine will then draw these gases into the combustion chamber where they are burned to help prevent the release of the gases into the atmosphere.
Exhaust gas recirculation (EGR). The EGR system meters about 3% to 7% of the exhaust gases back into the intake where the gases reduce the peak combustion temperature and prevent the oxygen (O2) and nitrogen (NO) from the air from combining to form oxides of nitrogen.
Catalytic converter. The catalytic converter is a unit located in the exhaust system usually close to the engine, which causes chemical changes in the exhaust gases.
On-board diagnostics means that the engine as well as the engine management systems can test itself for proper operation and alert the driver if a fault is detected. The warning lamp is called the malfunction indicator light (MIL) and is labeled “Check Engine” or “Service Engine Soon.” The onboard diagnostic system is currently in the second generation and is called OBD-II. Electronic hand-held testers, called scan tools, are needed to access (retrieve) stored diagnostic trouble codes (DTCs) and view sensor and system data.
Every engine requires many systems to function correctly.
COOLING SYSTEM While some older engines were air cooled, all engines currently in production are liquid cooled. Coolant is circulated by a water pump through passages in the cylinder block and head called water jackets. The coolant is a mixture of antifreeze and water to provide corrosion and freezing protection. After the coolant picks up the heat from the engine, it flows through a radiator, which cools the coolant by releasing the heat into the air. The temperature of the coolant is maintained by using a thermostat located in the coolant passage, which opens to allow coolant to flow to the radiator or closes until the coolant is hot enough to need cooling. LUBRICATION SYSTEM
All engines need a supply of lubricating oil to reduce friction and help to cool the engine. Most engines are equipped with an oil pan, also called an oil sump, containing 3 to 7 quarts (liters) of oil. An engine driven oil pump forces the oil under pressure through an oil filter, then to passages in the block and head called oil galleries, and then to all of the moving parts.
AIR INTAKE SYSTEM
All engines, both gasoline and diesel engines, draw air from the atmosphere. It requires about 9,000 gallons of air for each gallon of gasoline used. The air must be drawn where deep water in the road cannot be drawn into the engine. The air is then filtered by a replaceable air filter. After the air is filtered, it passes through a throttle valve and then into the engine through an intake manifold.
FUEL SYSTEM
POWERTRAIN OVERVIEW The purpose of the powertrain is to transfer the torque output of the engine to the drive wheels.
The fuel system includes the following compo-
nents and systems:
Fuel tank
Fuel lines and filter(s)
Fuel injectors
Electronic control of the fuel pump and fuel injection
REAR-WHEEL-DRIVE POWERTRAIN
A rear-wheel-drive vehicle uses the following components to transfer engine torque to the rear drive wheels:
Transmission. An automatic transmission usually uses planetary gearsets and electronic controls to change gear ratios. In a manually shifted transmission, the drivetrain contains a clutch assembly, which allows the driver to disengage engine torque from the transmission to allow the driver to shift from one gear ratio to another. The transmission contains gears and other assemblies that provide high torque output at low speeds for acceleration and lower torque output but at higher speeds for maximum fuel economy at highway speeds.
Drive Shaft. A drive shaft, also called a propeller shaft, is used to connect and transmit engine torque from the transmission to the rear differential. Universal joints (U-joints) are used to allow the rear differential to move up and down on the rear suspension and still be able to transmit engine torque.
The fuel injectors are designed to atomize the liquid gasoline into small droplets so they can be mixed with the air entering the engine. This mixture of fuel and air is then ignited by the spark plug.
STARTING AND CHARGING SYSTEM
Engine starting and charging systems, which include the battery, starting (cranking) system and charging system components and circuits.
IGNITION SYSTEM
The ignition system includes the ignition coil(s) which creates a high voltage spark by stepping up battery voltage using an ignition control module (ICM). The arc across
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FIGURE 1–9 A dash control panel used by the driver to control the four-wheel-drive system.
Differential. A differential is used at the rear of the vehicle and performs three functions:
Allows different axle speeds for cornering.
The differential increases the torque applied to the rear drive wheels by reducing the speed.
The differential also changes the direction of the applied engine torque and uses axle shafts to transfer the torque to the drive wheels.
FRONT-WHEEL-DRIVE POWERTRAIN
A front-wheel-drive vehicle uses a transaxle, which is a combination of a transmission and differential in one assembly. Drive axle shafts then transfer the engine torque to the front drive wheels from the output of the transaxle.
FOUR-WHEEL-DRIVE SYSTEM
There are many types of methods of powering all four wheels. Many include a transfer case to split engine torque to both the front and the rear wheels. SEE FIGURE 1–9.
ELECTRICAL/ELECTRONIC SYSTEMS OVERVIEW Early vehicles did not have an electrical system because even the ignition did not require a battery. Early engines used a magneto to create a spark instead of using electrical power from a battery as used today. The first electrical components on vehicles were batterypowered lights, not only for the driver to see the road, but also so others could see an approaching vehicle at night. Only after 1912 and the invention of the self-starter did the use of a battery become commonplace. Charles F. Kettering also invented the point-type ignition system about the same time as the self-starter. Therefore, the early batteries were often referred to as SLI batteries meaning starting, lighting, and ignition. From the 1920s into the 1950s other electrical components were added, such as radios, defroster fans, and horns. It was not until the 1960s that electrical accessories, such as air conditioning, power seats, and power windows, became common. Today’s vehicles require alternators that are capable of producing a higher amount of electricity than was needed in the past, and
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FIGURE 1–10 The alternator is in the heart of the electrical system.
the number of electronic components has grown to include every system in the vehicle, including:
A tire pressure monitoring system for the tires
Heated and cooled seats
Automatic climate control
Power windows
Security systems
Electric power steering
Electronic suspension
SEE FIGURE 1–10.
HEATING, VENTILATION, AND AIR CONDITIONING OVERVIEW Early model vehicles did not include any heaters or other methods to provide comfort for the driver and passengers. Most early vehicles were open with a simple removable top. Some had optional side curtains that provided all-weather protection. In the 1930s and 1940s when fully enclosed bodies became common, the vehicle manufacturers started to include heaters, which were small radiators with engine coolant flowing through them. About the same time and into the 1950s, about the only options that many vehicles had were a radio and heater, abbreviated R & H. Today, air-conditioning systems are on most vehicles and incorporate defrosters and passenger compartment heating, often in two zones for maximum comfort of the driver and passenger. Additional related comfort options today include heated and cooled seats and heated steering wheels.
EIGHT AREAS OF AUTOMOTIVE SERVICE In 1972, the National Institute for Automotive Service Excellence, a non-profit organization known as simply ASE, created a series of eight tests that cover the major vehicle systems. SEE FIGURE 1–11.
area are rear differential diagnosis and repair plus four-wheel-drive component diagnosis and repair.
SUSPENSION AND STEERING (A4) This content area includes steering and suspension system diagnosis and repair, including wheel alignment diagnosis and adjustments, and wheel and tire diagnosis and repair procedures. BRAKES (A5)
The brake content area includes the diagnosis and repair of the hydraulic system, drum and disc brake systems, plus power assist units, antilock braking, and traction control systems.
FIGURE 1–11 Test registration booklet that includes details on all vehicle-related certification tests given by ASE.
ELECTRICAL/ELECTRONIC SYSTEMS (A6) This content area includes many systems, including the battery, starting, charging, lighting, gauges, and accessory circuit diagnosis and repair. HEATING AND AIR CONDITIONING (A7)
ENGINE REPAIR (A1)
This content area includes questions related to engine block and cylinder head diagnosis and service, as well as the lubrication, cooling, fuel, ignition, and exhaust systems inspection and service.
AUTOMATIC TRANSMISSION (A2)
This content area includes general automatic transmission/transaxle diagnosis, including hydraulic and electronic related systems.
MANUAL DRIVE TRAIN AND AXLES (A3) This content area includes clutch diagnosis and repair, manual transmission diagnosis and repair, as well as drive shaft, universal, and constant velocity joint diagnosis and service. Also included in this content
The heating and air-conditioning content area includes air-conditioning service, refrigeration systems, heating and engine cooling systems diagnosis and repair, as well as refrigerant recovery, recycling, handling, and retrofit.
ENGINE PERFORMANCE (A8) The engine performance content area includes diagnosis and testing of those systems responsible for the proper running and operation of the engine. Included in this area are general engine diagnosis, ignition and fuel systems, as well as emission control and computerized engine control diagnosis and repair. This textbook covers the content of all eight ASE areas plus all of the background and fundamental information needed by technicians.
REVIEW QUESTIONS 1. In 1900, what was the most produced vehicle powered by?
5. The powertrain consists of what components?
2. What parts are included in the vehicle chassis?
6. What are the eight automotive service content areas?
3. Why were early engines called flat heads? 4. What is the difference between a unit-body and body-on-frame vehicle?
CHAPTER QUIZ 1. The first self-propelled vehicle that used an OTTO cycle fourstroke gasoline engine was produced in ______________. a. 1885 c. 1902 b. 1900 d. 1908 2. Early vehicles were constructed mostly of what material? a. Steel b. Cast iron c. Wood d. Tin 3. Which component is not part of the chassis system? a. Frame b. Electrical system c. Suspension d. Brakes
4. Early engines were called flat head design because they ______________. a. Were only inline engines b. Did not include valves c. Used valves beside the cylinder d. Used spark plugs at the top of the cylinders 5. A V-type engine could have how many cylinders? a. 4 c. 8 b. 6 d. All of the above 6. What component regulates the temperature of the coolant in an engine? a. Cooling (water) jackets c. Cooling fan(s) b. Thermostat d. Radiator
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7. A malfunction indicator light (MIL) on the dash may be labeled ______________. a. Check engine c. MIL b. Service vehicle soon d. MAL
9. A four-wheel drive vehicle often uses a ______________ to transmit torque to all four wheels. a. Drive shaft c. Transaxle b. U-joint d. Transfer case
8. To retrieve stored diagnostic trouble codes, a service technician needs a ______________. a. Paper clip b. Desktop computer c. Wireless connection to an electronic tester d. Scan tool
10. Automotive service systems are generally separated into how many content areas? a. 4 c. 8 b. 6 d. 10
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2
CAREERS IN THE AUTOMOTIVE SERVICE INDUSTRY
OBJECTIVES: After studying Chapter 2, the reader will be able to: • Describe automotive service-related positions. • Discuss the level of training and experience needed for each position. • Describe the technical skills needed for each position. • Explain the relationship of the service manager to others in a shop and company. KEY TERMS: Entrepreneur 14 • On-the-job training (OJT) 10 • Parts counter person 13 • Service advisor 12 • Service consultant 12 • Service manager 12 • Service writer 12 • Shop foreman 12 • Team leader 12 • Technician (tech) 8 • VIN 11 • Work order 11
THE NEED FOR AUTOMOTIVE TECHNICIANS The need for trained and skilled automotive technicians is greater than ever for several reasons, including:
Vehicles are becoming more complex and require a higher level of knowledge and skills.
Electrical and electronic components and sensors are included throughout the vehicle.
Construction of parts and materials being used has changed over the last few years, meaning that all service work must be done to specified procedures to help avoid damage being done to the vehicle.
Increasing numbers of different types of lubricants and coolants make even routine service challenging.
All of the above issues require proper training and the ability to follow factory specified procedures to ensure customer satisfaction. The number of service technicians needed is increasing due to more vehicles on the road. A good service technician can find work in almost any city or town in the country, making the career as a professional service technician an excellent choice.
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THE NEED FOR CONTINUOUS VEHICLE SERVICE Vehicles are lasting longer due to improved materials and more exacting tolerances. Every year, vehicles are being driven farther than ever before. It used to be (in the 1950s) that the life of a vehicle was considered to be 100,000 miles or 10 years. Now achieving 200,000 miles without a major repair is common with proper maintenance and routine service. However, even the amount of needed routine service has been reduced due to changes in the vehicles, such as radial tires that now last 40,000 miles instead of older tires which were worn out and needed to be replaced every 15,000 miles.
WARRANTIES A warranty is a guarantee to the purchaser of a vehicle that it will function as specified. The warranty covers the quality and performance of the product and states the conditions under which the warranty will be honored. Vehicle warranties vary but all warranties indicate a time and mileage restriction. The expressed warranties often include the following areas:
New vehicle limited warranty that covers most components and is commonly called a bumper-to-bumper policy.
Powertrain warranty covers the engine, transmission/ transaxle, and final drive units. This coverage usually is longer than the bumper-to-bumper coverage.
Sheet metal rust through warranty is usually longer than the bumper-to-bumper and powertrain warranty and covers rust if a hole occurs starting from inside the outer metal surface of the body.
Emission control device warranties depend on the emission rating, the warranty coverage of the powertrain control module (PCM), and the catalytic converter and are covered for 8 years and 80,000 miles up to 10 years and 150,000 miles.
Vehicle warranties, unless an emergency repair, must be performed at a dealership, which is certified by the vehicle manufacturer to perform the repairs. At the dealership, the technician performing the repair must also be certified by the vehicle manufacturer. All technicians should be familiar with what may be covered by the factory warranties to help ensure that the customer does not have to pay for a repair that may be covered. While warranties do cover many components of the vehicle, wear and service items are not covered by a warranty in most cases and therefore, offer excellent opportunity for additional service work for trained automotive technicians.
FIGURE 2–1 A service technician checking for a noise of a vehicle in a new-vehicle dealership service department.
INCREASING AGE OF A VEHICLE
The average age of a vehicle on the road today has increased to older than nine years. This trend means that more vehicles than ever are not covered by a factory warranty and are often in need of repair. Aftermarket warranties also can be used at most repair facilities, making it very convenient for vehicle owners.
TECHNICIAN WORK SITES
FIGURE 2–2 A typical independent service facility. Independent garages often work on a variety of vehicles and perform many different types of vehicle repairs and service. Some independent garages specialize in just one or two areas of service work or in just one or two makes of vehicles.
Service technician work takes place in a variety of work sites including:
NEW VEHICLE DEALERSHIPS Most dealerships handle one or more brands of vehicle, and the technician employed at dealerships usually has to meet minimum training standards. The training is usually provided at no cost online or at regional training centers. The dealer usually pays the service technician for the day(s) spent in training as well as provides or pays for transportation, meals, and lodging. Most dealerships offer in house on-line training with minimum off-site training. SEE FIGURE 2–1. INDEPENDENT SERVICE FACILITIES
These small- to medium-size repair facilities usually work on a variety of vehicles. Technicians employed at independent service facilities usually have to depend on aftermarket manufacturers’ seminars or the local vocational school or college to keep technically up-to-date. SEE FIGURE 2–2.
MASS MERCHANDISER
Large national chains of vehicle repair facilities are common in most medium- and large-size cities. Some examples of these chains include Sears, Goodyear, Firestone, and NAPA, as shown in SEE FIGURE 2–3. Technicians employed by these chains usually work on a wide variety of vehicles. Many of the companies have their own local or regional training sites designed to train beginning service technicians and to provide update training for existing technicians.
FIGURE 2–3 This NAPA parts store also performs service work from the garage area on the side of the building.
SPECIALTY SERVICE FACILITIES Specialty service facilities usually limit their service work to selected systems or components of the vehicle and/or to a particular brand of vehicle. Examples of specialty service facilities include Midas, Speedy, and AAMCO Transmissions. Many of the franchised specialty facilities have their own technician training for both beginning and advanced technicians. SEE FIGURE 2–4. FLEET FACILITIES Many city, county, and state governments have their own vehicle service facilities for the maintenance and
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repair of their vehicles. Service technicians are usually employees of the city, county, or state and are usually paid by the hour rather than on a commission basis. SEE FIGURE 2–5.
TECHNICIAN JOB CLASSIFICATIONS There are many positions and jobs in the vehicle service industry. In smaller service facilities (shops), the duties of many positions may be combined in one job. A large city dealership may have all of the following vehicle service positions. A technician is often referred to as a tech.
LUBE TECH/QUICK SERVICE TECHNICIAN A lubrication technician should be trained in the proper use of hand tools and instructed how to properly service various types of vehicles. The training could be on-the-job (OTJ) or could be the result of high school or college automotive training. Some larger companies provide in-house training for new technicians and as a result they are trained to perform according to a specified standard. It is important that the lubrication technician double-check the work to be certain that the correct viscosity oil has been installed and to the specified level. The oil plug and oil filter must also be checked for leakage. Lubrication technicians are trained to perform routine services including:
Oil and oil filter change
Chassis lubrication
Fluids check and refill
Tire inflation checks
Accessory drive belt inspection
Air filter check and replacement
Cabin filter replacement
Windshield wiper blade replacement
As a result of these tasks the lubrication technician should be skilled in hoisting the vehicle and able to handle the tasks efficiently and in minimum time.
FIGURE 2–4 Midas is considered to be a specialty service shop.
NEW VEHICLE PREPARATION FOR DELIVERY A new entry-level position at a dealership often includes preparing new vehicles for delivery to the customer. This is often referred to as “new car prep.” The duties performed for new vehicle preparation are generally learned on the job. The vehicle manufacturer publishes guidelines that should be followed and it is the responsibility of the
FIGURE 2–5 A school bus garage is a typical fleet operation shop that needs skilled service technicians.
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new vehicle preparation person to see that all items are checked and serviced, and all associated paperwork is completed. The activities normally associated with preparing a new vehicle for delivery include:
Installing wheel center caps or wheel covers (if used)
Installing roof racks, running boards, and other dealerinstalled options
Checking and correcting tire pressures
Why Is the Work Order Important? The work order is a legal document that includes the description of the vehicle and the work requested by the customer. The customer then signs the work order authorizing that the stated work be performed. If there are additional faults found then the shop must notify the customer and get permission to change the amount or extent of the work originally authorized. As work is performed on the vehicle, the parts used and the labor operation performed are added. This creates a complete file on the repair. This means that the vehicle has to be properly identified by including the vehicle identification number (VIN) on the work order. There is only one vehicle with that VIN, yet there may be many “white Chevrolet pickup trucks.” The work order is the paper trail that shows all operations, labor times, and parts used when the vehicle was in control of the shop. A work order is often required even when the technician is working on his or her own vehicle.
NOTE: Many vehicle manufacturers ship the vehicles to the dealer with the tires overinflated to help prevent movement of the vehicle during shipping.
Checking all fluids
Checking that everything works including the remote key fob and all accessories
Ordering any parts found to be broken, missing, and damaged in transit
Removing all protective covering and plastic from the seats, carpet, and steering wheel
Washing the vehicle
GENERAL SERVICE TECHNICIAN A general service technician usually has training as an automotive technician either in one or more of the following:
High school—Technical or vocational school or a comprehensive high school that has an Automotive Youth Education System (AYES) program or NATEF certification.
College or technical school—Usually a two-year program that can earn the student an associate’s degree.
Career college or institute—Usually a 6-month to 12-month program earning the graduate a certificate.
Automotive service technicians perform preventative maintenance, diagnose faults, and repair automotive vehicles and light trucks. Automotive service technicians adjust, test, and repair engines, steering systems, braking systems, drivetrains, vehicle suspensions, electrical systems and air-conditioning systems, and perform wheel alignments. In large shops, some technicians specialize in repairing, rebuilding, and servicing specific parts, such as braking systems, suspension, and steering systems. In smaller shops, automotive service technicians may work on a wider variety of repair jobs. Automotive service technicians begin by reading the work order and examining the vehicle. To locate the cause of faulty operation and repair it, a technician will:
Verify customer concern
Use testing equipment, take the vehicle for a test-drive, and/ or refer to manufacturer’s specifications and manuals
Dismantle faulty assemblies, repair, or replace worn or damaged parts
Reassemble, adjust, and test the repaired mechanism Automotive service technicians also may:
Perform scheduled maintenance services, such as oil changes, lubrications, and filter replacement
may be required. The work is sometimes noisy and dirty. There is some risk of injury involved in working with power tools and near exhaust gases. SKILLS AND ABILITIES The work is most rewarding for those who enjoy doing precise work that is varied and challenging. Also, technicians usually achieve job security and a feeling of independence. To be successful in the trade, automotive service technicians need:
Good hearing, eyesight, and manual dexterity (ability to work with hands)
Mechanical aptitude and interest
The ability to lift between 25 and 50 pounds (11 and 25 kilograms)
The willingness to keep up-to-date with changing technology
A working knowledge of electricity, electronics, and computers is also required for many service procedures. EMPLOYMENT AND ADVANCEMENT. Automotive service technicians are employed by automotive repair shops, specialty repair shops, service facilities, car and truck dealerships, and by large organizations that own fleets of vehicles. Experienced automotive service technicians may advance to service manager or shop foreman. Some automotive service technicians open their own repair facilities. Many technicians can also start work in a shop or dealership and learn on the job. Most technicians keep up-to-date by attending update seminars or training classes on specific topics throughout the year. Specific tasks performed by a general service technician can include the following:
All of the tasks performed by the lubrication technician.
Engine repairs including intake manifold gasket replacement; cylinder head replacement; and oil and water pump replacement plus other engine-related tasks.
Brake system service and repair including disc brakes; drum brakes; parking brake; and antilock brake (ABS) diagnosis and service.
Advise customers on work performed, general vehicle conditions, and future repair requirements
WORKING CONDITIONS Most automotive service technicians work a 40-hour, five-day week. Some evening, weekend, or holiday work
FREQUENTLY ASKED QUESTION
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Suspension-related service including tire inspection and replacement; shock and strut replacement; servicing or replacing wheel bearings; performing steering component inspection and parts replacement; and performing wheel alignment and vibration diagnosis. Electrical-related diagnosis and repair including starting and charging problems; correcting lighting and accessory faults; and general service such as light bulb replacement and key fob reprogramming. Heating, ventilation and air conditioning work usually involves the use of diagnostic and service equipment that requires special training and certification if working with refrigerants. Engine performance-related diagnosis and repair including replacing fuel pumps and filters; cleaning or replacing fuel injectors; service ignition system components; solving emissions-related failures; and determining the cause and correcting “Check Engine” lights.
Manual transmission service and repairs including replacing clutches; adjusting, or replacing clutch linkage; and performing four-wheel-drive diagnosis and service procedures.
Automatic transmission service and repairs including performing routine automatic transmission service; removing and replacing automatic transmissions; servicing differentials, transmissions/ transaxles and performing diagnosis and service checks including fluid pressure and scan tool diagnosis.
The vehicle is then driven by the service technician to verify the repair.
TECHNICIAN TEAM LEADER
A team leader is an experienced service technician who is capable of performing most if not all of the work that the shop normally handles. The team leader then assigns work to others in the group based on the experience or competency of the technician. The team leader then checks the work after it has been completed to be sure that it has been correctly performed. The number of hours of labor for each member of the team is totaled each pay period. Each member of the team is paid an equal share of the time but at different rates. The team leader gets a higher per hour rate than the others on the team. The rate of pay per hour is based on the level of training and experience. A beginning technician may or may not be paid as part of the total team hours depending on how the team system is organized. While some shops do not use teams, many large shops or dealerships have two or more teams. The advantage of a team-type organization is that everyone on the team looks out and helps each other if needed because they are all paid based on the number of hours the team generates. The team leader performs the duties of a shop foreman but only for those members on the team and not the entire shop. The team leader is under the direction and control of the service manager.
SHOP FOREMAN
A shop foreman (usually employed in larger dealerships and vehicle repair facilities) is an experienced service technician who is usually paid a salary (so much a week, month, or year). A shop foreman is a knowledgeable and experienced service technician who keeps up-to-date with the latest vehicle systems, tools, and equipment. Typical shop foreman’s duties include:
Assisting the service manager
Verifying that the repair is completed satisfactorily
The shop foreman is under the direction and control of the service manager.
SERVICE ADVISOR A service advisor, also called a service writer or service consultant, is the person at the dealership or shop designated to communicate the needs of the customer and accurately complete a work order. A service advisor should:
Have a professional appearance
Be able to speak clearly
Be able to listen carefully to the customer
Write neatly and/or type accurately
Be familiar with industry and shop standards and procedures
Most service advisors would benefit from taking a short course on service advising skill development and interpersonal relationship building. A service advisor should be familiar with the operation of the vehicle, but not to the same level as a service technician. A service advisor should not diagnose the problem, but rather state clearly on the work order what, when, and where the problem occurs so that the service technician has all the needed information to make an accurate diagnosis. SEE FIGURE 2–6 for an example of a typical work order. The service advisor’s duties include: 1. Recording the vehicle identification number (VIN) of the vehicle on the work order 2. Recording the make, model, year, and mileage on the work order 3. Carefully recording what the customer’s complaint (concern) is so that the service technician can verify the complaint and make the proper repair 4. Reviewing the customer’s vehicle history file and identifying additional required service 5. Keeping the customer informed as to the progress of the service work A service advisor must be at the shop early in the morning to greet the customers and often needs to stay after the shop closes for business to be available when the customer returns at the end of the day.
SERVICE MANAGER
The service manager rarely works on a vehicle but instead organizes the service facility and keeps it operating smoothly. A service manager can be a former service technician or in many larger dealerships, a business major graduate who is skilled at organization and record keeping. The service manager typically handles all of the paperwork associated with operating a service department.
NOTE: In a small shop, the shop owner usually performs all of the duties of a shop foreman and service manager, as well as the lead technician in many cases. Typical duties of a service manager include:
Establishing guidelines to determine the technicians’ efficiency
Supervising any warranty claims submitted to the vehicle manufacturer or independent insurer
Test-driving the customer’s vehicle to verify the customer concern (complaint)
Assigning work to the service technicians
Evaluating and budgeting for shop tools and equipment
Assisting the service technicians
Helps maintain the shop and shop equipment
Establishing service department hours of operation and employee schedules
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FIGURE 2–6 Typical work order. (Courtesy of Reynolds and Reynolds Company)
TECH TIP Check the Vehicle before Work Is Started As part of the work order writing process, the service advisor should look over the vehicle and make a written note of any body damage that may already exist. If any damage is noted it should be mentioned to the customer and noted on the work order. Often the customer is not aware of any damage especially on the passenger side and thus would blame the shop for the damage after the service work was performed.
Assigning working hours and pay for technicians and others in the service department
must be able to greet and easily talk to customers and technicians. A parts counter person must also have computer skills and the willingness to help others. The parts counter person usually has the following duties:
Greet the customer or technician
Locate the correct parts for the service technician or customer
Suggest related parts (retail customers)
Stock shelves
Check in delivered parts
Take inventory
Keep the parts department clean
Help the parts manager
Establishing procedures and policies to keep the service area clean and properly maintained
SEE FIGURE 2–7.
PARTS MANAGER
The specific duties of a parts manager
usually include:
PARTS-RELATED POSITIONS The parts manager and other parts personnel such as the parts counter person are responsible for getting the correct part for the service technician.
PARTS COUNTER PERSON
A parts counter person often learns job skills by on-the-job training. A good parts counter person
Ordering parts from the vehicle manufacturers and aftermarket companies
Stocking parts
Organizing the parts department in a clear and orderly fashion
Locating parts quickly within the parts department
Developing contacts with parts departments in other local dealerships so that parts that are not in stock can be purchased quickly and at a reasonable cost
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FREQUENTLY ASKED QUESTION
What Is an Entrepreneur? An entrepreneur is a person who starts and operates a business. Many service technicians want to eventually own their own shop and become an entrepreneur. However, operating a shop involves many duties and responsibilities that many service technicians lack, including: • • • • • • • • •
FIGURE 2–7 Parts counter people need to know many aspects of automotive repair to be effective with customers.
While at first it may seem like owning your own shop would be great, a good technician can often make more money, and have fewer headaches, by simply working for someone else.
SALES JOBS—USED VEHICLES; NEW VEHICLES SALESPERSON When a vehicle is sold, it generates a potential customer for the service department. New and many used vehicle sales dealerships employ salespeople to help the customer select and purchase a vehicle. The salesperson should have excellent interpersonal skills, as well as be familiar with the local and regional laws and taxes to be able to complete all of the paperwork associated with the sale of a vehicle. The usual duties of a vehicle salesperson include:
Greet the customer Introduce yourself and welcome the customer to the store Qualify the customer as to the ability to purchase a vehicle
Demonstrate and ride with the customer on a test-drive
Be able to find the answer to any question the customer may ask about the vehicle and/or financing
Be able to complete the necessary paperwork
Follow up the sale with a telephone call or card
SALES MANAGER
A sales manager is an experienced salesperson who is able to organize and manage several individual salespeople. The duties of a sales manager include:
Establish a schedule where salespeople will be available during all hours of operation
Consult with salespeople as needed on individual sales
Train new salespeople
Conduct sales promotion activities
Attend or assign someone to attend vehicle auctions to sell and/or purchase vehicles
Keep up-to-date with the automotive market
Purchase vehicles that sell well in the local market
Answer to the general manager or dealership principal
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Bookkeeping and accounting skills Tax preparation (local, state, and federal) Sales tax collection and payment Health insurance arrangements for employees Unemployment compensation payments Workers’ compensation payments Uniform payment Real estate taxes Garage keepers liability insurance
OTHER CAREERS IN THE AUTOMOTIVE INDUSTRY Other careers in the automotive industry include:
Sales representative for automotive tools and equipment
Technical trainers
Technical school instructors
Wholesale parts warehouse management
Insurance adjuster
Automotive technical writer
Warranty claim examiner
TYPICAL AUTOMOTIVE ORGANIZATION ARRANGEMENT LARGE COMPREHENSIVE NEW VEHICLE DEALER
A typical dealership includes many levels because there are many departments such as sales (new and used) as well as the service, parts and body shops to manage. SEE FIGURE 2–8.
INDEPENDENT SHOP.
An independent shop may or may not have a shop foreman depending on the number of technicians and the volume of work. Larger independent shops have a shop foreman, whereas at smaller shops, the owner is the shop foreman. SEE FIGURE 2–9.
DEALERSHIP PRINCIPAL (OWNER)
GENERAL MANAGER
SERVICE MANAGER
PARTS MANAGER
SHOP FOREMAN
SERVICE TECHNICIAN
BODY SHOP MANAGER
NEW VEHICLE MANAGER
USED VEHICLE MANAGER
PARTS RUNNER
PAINTER
OFFICE STAFF
OFFICE STAFF
COUNTER PERSON
BODY TECHNICIAN
SALESPEOPLE
SALESPEOPLE
SERVICE ADVISOR
FIGURE 2–8 A typical large new vehicle dealership organizational chart.
SHOP OWNER/MANAGER
OFFICE STAFF
SERVICE TECHNICIAN
FIGURE 2–9 A typical independent shop organizational chart.
REVIEW QUESTIONS 1. What should be included on a work order? 2. Why should a vehicle be inspected when the work order is being written? 3. What tasks are usually performed by a general service technician?
4. What duties are performed by the shop foreman and service manager? 5. What duties are performed by a parts counter person? 6. What duties are performed by vehicle salespeople?
CHAPTER QUIZ 1. A service advisor is called a ______________. a. Shop foreman c. Service writer b. Service manager d. Technician 2. What is not included on a work order? a. Customer’s mother’s maiden name b. VIN c. Mileage d. Description of work requested 3. All of the following are usual duties of a lube technician except ______________. a. Oil change c. Water pump replacement b. Air filter replacement d. Accessory drive belt inspection 4. New vehicle preparation is usually an entry-level vehicle service position and usually involves what duties? a. Installing dealer-installed options b. Correcting tire pressures c. Removal of all protective coverings and plastic d. All of the above 5. What is not a duty of a general service technician? a. Have the customer sign the work order b. Order the parts needed c. Diagnose the customer’s concern d. Perform vehicle repair procedures
6. Which description best fits the role of a service advisor? a. A skilled technician b. A beginning technician c. A customer service representative d. A money manager 7. Two technicians are discussing the duties of a shop foreman and a service manager. Technician A says that a shop foreman diagnoses vehicle problems. Technician B says that the service manager usually repairs vehicles. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 8. Who is the person that greets the service customer and completes the work order? a. Service manager c. Service writer b. Service advisor d. Either b or c 9. Which job would be concerned with the maintenance of the shop equipment? a. Service manager c. Shop owner b. Shop foreman d. Any ofw the above 10. Which job would be concerned with working hours and pay? a. Service manager c. Service advisor b. Shop foreman d. Service technician
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3
STARTING A CAREER IN THE AUTOMOTIVE INDUSTRY
OBJECTIVES: After studying Chapter 3, the reader will be able to: • Explain the steps and processes for applying for a job. • Describe what the resume should include. • Explain why having a good driving record is important to a shop owner. • Discuss how to prepare for a career in the automotive industry. KEY TERMS: Apprentice program 17 • Clock-in 20 • Clock time 20 • Commission pay 21 • Cooperative education 17 • Entrepreneur 23 • Federal tax 21 • FICA 21 • Flat-rate 21 • Gross 21 • Housing expense 22 • Incentive pay 21 • Job shadowing 16 • Net 21 • Part-time employment 17 • Reference 19 • Resume 18 • Soft skills 17 • State tax 21 • Straight time 20
TECH TIP
PREPARING FOR AN AUTOMOTIVE SERVICE CAREER
If in Doubt, Ask No one expects a beginning service technician to know everything, but other technicians do not know what you do or do not know. It is usually assumed that the beginning technician will ask for help if they think they need the help. However, asking for help is very rare and requires the beginning technician to admit that they do not know something. Not asking for help can cause harm to the vehicle or the service technician. If in doubt— always ask. No one will be upset and learning the answer to your question will help in the learning experience.
DESIRE AND INTEREST
If a person has an interest in automobiles and trucks and likes computers, the automotive service field may be a good career choice. Computer skills are needed in addition to hands-on skills for several reasons, including:
Service information, such as diagnostic procedures and specifications, is commonly available in electronic format.
Work orders are commonly written and sent to the technician electronically. The technician therefore needs typing skills to type the steps taken during the service or repair procedures.
Hand tools and tool usage. Owning and experience using hand tools is important for a service technician. All service technicians are expected to be able to remove and replace parts and components as needed in a timely manner using proper tools and techniques.
Technical knowledge. While knowing how all aspects of the vehicle works is not expected of a beginning service technician, it is important that the technician have a basic understanding of the parts and procedures needed at least for routine service procedures.
Warranty claims are often submitted by the Internet and computer skills are needed to quickly and accurately submit claims and answer questions from the insurance company.
Interest in vehicles is also very important toward being successful as a professional service technician. Most technicians enjoy working on vehicles, not only professionally, but also during their spare time. Many technicians own a project vehicle, which could include:
Drag race vehicle
Race vehicle used in road racing
A fun vehicle used on sunny weekend days and evenings
Motorcycle
Snowmobile or jet ski
Truck for rock crawling
TECHNICAL KNOWLEDGE AND SKILLS The enjoyment of being involved with vehicles is very important because the job of servicing and repairing automobiles and trucks can be hard and dirty work. Many men and women enjoy being around and learning about the details of vehicle operation. With these desires and interest, working in the automotive service field is a great career. Technical information, skills, and tools needed include:
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JOB SHADOWING
A great way to see what it is really like to work as a service technician is to follow a professional around for a day or more. Job shadowing is usually arranged through an automotive program, and the shop or dealership has agreed to allow someone into the shop area to observe. While it does allow the student to observe, job shadowing does not allow the person to perform any work or help the technician in any way. During the day, the person who is job shadowing has to wear all personal protective equipment as required by the technician and must observe all safety regulations. The advantages of job shadowing include:
Being able to observe a typical day in the life of an automotive technician
Being able to talk to the working technician about what is being done and why
Being able to observe other technicians and seeing the various skill levels that often exist in a shop
COOPERATIVE EDUCATION PROGRAMS Cooperative education programs are formal programs of study at a high school or college where the student attends classes at the school, and also works at a local shop or dealership. If a cooperative education program is held at the high school level, the work at the shop or dealership occurs during the afternoon or evening and during the summer between the junior and senior year. The most common high school cooperative program is called AYES, which means Automotive Youth Education System (see www.ayes .org). The vehicle manufacturers involved in this program include:
DEVELOPING AN EMPLOYMENT PLAN An employment plan is an evaluation of your skills, interest, and talents. Selecting a career is different than getting a job. A typical job, while it does involve some training, usually can be learned in a few days to several months. However, a career requires many years to achieve competence. Therefore, selecting a career should require a thorough self-examination to determine what your true interest is in a particular career field. Some items that you should enjoy or would be willing and able to learn include:
Working with your hands, using tools and equipment
General Motors
Computer usage, including typing skills Working in an area where lifting is often required
Chrysler
Toyota
Honda
Being able to read, understand, and follow service information, technical service bulletins, and work orders
Nissan
BMW
Being able to perform diagnostic work and figure out the root cause of a problem
Kia
Subaru
Hyundai
If the cooperative education program is held at a community college, the work at the dealership occurs around the training sessions, usually the first or second half of a semester or on alternative semesters. The most common college programs include:
General Motors ASEP (Automotive Service Educational Program) (see www.gmasepbsep.com)
Ford ASSET (Automotive Student Service Educational Program) (see www.fordasset.com)
Chrysler CAP (College Automotive Program) (see www.chryslercap.com)
Toyota T-TEN (Toyota Technician Education Network) (see www.toyota.com/about/tten/index.html)
Another factory sponsored program open to those who have already completed a postsecondary automotive program is BMW STEP (Service Technician Education Program) (see www .bmwusa.com/about/techtraining.html).
APPRENTICE PROGRAMS An apprentice program involves a beginning service technician working at a shop or dealership during the day and attending training classes in the evening. The key advantage to this type of program is that money is being earned due to full-time employment and getting on-the-job training (OJT) during the day. Often the shop or dealership will help pay for training. While this program usually takes more than two years to complete, the work performed at the shop or dealership usually becomes more technical as the apprentice becomes more knowledgeable and gets more experienced. PART-TIME EMPLOYMENT
Working part time in the automotive service industry is an excellent way to get hands-on experience, which makes it easier to relate classroom knowledge to everyday problems and service issues. Working part time gives the student technician some flexibility as to college schedules and provides an income needed for expenses. Often part-time employment becomes full-time employment so it is important to keep attending technical classes toward becoming an asset to the company.
SOFT SKILLS In addition, any career, including being a service technician, requires many people skills, often called soft skills. These people-related skills include:
Working cooperatively with other people
Communicating effectively with others verbally (speech) and in writing
Working as a member of a team for the benefit of all
Being able to work by yourself to achieve a goal or complete a job assignment
Being able to lead or supervise others
Willingness to work with others with a different background or country of origin
While it is almost impossible to be able to answer all of these questions, just looking at these items and trying to identify your interests and talents will help in your selection of a career that gives you lifelong satisfaction.
LOCATING
EMPLOYMENT POSSIBILITIES Locating where you wish to work is a very important part of your career. Of course, where you would like to work may not have an opening and you may have to work hard to locate a suitable employer. First, try to select a shop or dealership where you think you would like to work because of location, vehicles serviced, or other factors. Ask other technicians who have worked or are presently working there to be sure that the location would meet your needs. If looking for employment through a want ad in a newspaper or employment Web site, check the following:
Job description. Is this a position that could advance into a more technical position?
Tools needed. Most professional service technician positions require that the technician provide their own tools. (The shop or dealership provides the shop equipment.) Do you have the tools needed to do the job?
Hours needed. Are you available during the hours specified in the ad?
Drug testing. Is a drug test needed for employment and are you prepared to pass?
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Educational Information
PREPARING A RESUME A resume is usually a one-page description of your skills, talents, and education. It is used by prospective employers to help narrow the field of applicants for a job or position. The number one purpose of a resume is to obtain a job interview. A good resume should include the following items:
Highest education level achieved
Major, if in a college or in a training program
Experience and Skills
Work or volunteer experience that may be helpful or useful to an employer. For example, if you took a course in welding, this may be useful to a shop owner who is looking for a service technician who could do welding, even though this fact was not included in the job posting.
A valid driver’s license is a must for most professional service technicians.
A good driving record. Often the shop insurance company will not allow a shop owner to hire a technician with a poor driving record.
Personal Information
Full given name (avoid nicknames)
Mailing address (do not use a post office [PO] box)
Telephone and/or cell phone number
E-mail address
Avoid using dates which could indicate your age
Sample Resume Personal Information: James Hartman 301 Main Street City, State 40005 Telephone: (555) 555-0170 Cell: (555) 555-1139 Career Goal: To become a certified ASE master technician and work at a new vehicle dealership. Experience: 2006 to the present—I work part time (20 hours per week) at Miller Service performing routine vehicle service, including oil changes, tire balancing, brake repairs, timing belt replacement, and intake manifold gasket replacement. I have assisted with suspension and air-conditioning repairs and own a basic set of hand tools. Education: High school diploma from Central High School, City, State 40010. I am finishing a two-year automotive technician training program at City College, City, State 40010 (to be completed May 15). Additional Training and Certification: ASE certified in Brakes and Engine Repair. Attended a seminar on wide-band oxygen sensors and electronic throttle control at a local automotive service exposition. Other Skills and Interests: I am restoring a 1969 Chevrolet Camaro, including all mechanical repairs and upgraded suspension system. References: Available upon request.
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REFERENCES
A reference is someone who is willing to tell a possible employer about you, including your skills and talents, as well as your truthfulness and work habits. Most employers would like to see someone who is familiar with you and your family, such as a priest, minister, or elder in your church. Some teachers or coaches also can be asked to be a reference. Always ask the person for approval before including the person on your list of references. Ask the reference to supply you with a written recommendation. Some references prefer to simply fill out a reference questionnaire sent by many companies. If a reference sends you a written recommendation, have copies made so they can be included with your resume.
PREPARING A COVER LETTER When answering an advertisement in a newspaper or magazine, be sure to include the details of where you saw the ad in your cover letter to the employer. For example: “I am applying for the position as an entry-level service technician as published in the August 15 edition of the Daily News.” If the requirements for the position are listed, be sure to include that you do have the specified training and/or experience and the tools needed for the job. If calling about a position, be sure to state that you are applying for the position posted and ask to speak to the correct person or to the person mentioned in the ad.
Sample Cover Letter
301 Main Street City, State 40005 Telephone: (555) 555-0170 Cell: (555) 555-1139 Date Mr. John Smith Smith Dealership 800 North Street City, State 40010 Dear Mr. Smith: I am applying for the position of general service technician at your dealership as advertised in the Sunday, January 7, edition of the Daily News. I am currently finishing my studies in Automotive Technology at City College and have worked part time at Miller Service for the past two years. I am ASE certified in Brakes and Engine Repair and plan to become certified in all eight areas. I have my own tools and currently can work in the afternoons and evenings. After May 15, I will be able to work full time after completing my automotive courses. I look forward to the opportunity to discuss my skills and resume in an interview. Thank you for your consideration. Sincerely, James Hartman Enclosure (1)
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TECH TIP Always Be Truthful No one is smart enough to be a liar. If you say something that is not true, then you have to remember what was said forever or your lie will often be discovered. If asked about your experience or knowledge, try to be as truthful as possible. Facts and skills can be learned and not knowing how to do everything that a shop may be involved with is not an indication that you will be rejected from the job opening.
Be clean shaven or have beard/mustache neatly trimmed
Have clean hair
Avoid facial jewelry
During the interview, try to answer every question honestly. Emphasize what you are capable of providing to the shop including:
Enthusiasm
Experience
Willingness to work
Willingness to work long hours and/or long weeks
AFTER THE INTERVIEW CONTACTING POTENTIAL EMPLOYERS When a job opening is posted in a newspaper or it is mentioned by a friend, most experts recommend that you visit the shop or dealership in person to see where the job is located, the condition of the buildings, and the surrounding areas. This trip could also be used for you to submit your resume and cover letter in person unless the company indicates otherwise. Be prepared to be interviewed when submitting your resume. Even if the position has already been filled, the trip gives you experience in meeting people and seeing the shop, which helps increase your confidence during the job search. Searching for a job is a full-time job in itself. Be prepared every day to answer ads, search employment web sites and travel to shops or dealerships.
COMPLETING THE EMPLOYMENT APPLICATION Most businesses require that an employment application be completed because it not only asks for all necessary personal information needed, but also references and emergency contacts. Most employment application forms ask for previous employers, the names and telephone numbers of contact people, and other information which you may not remember. It is wise to have all of the information written down ahead of time and take it with you for reference when completing the application. Always answer questions honestly and as thoroughly as possible. Never lie on an employment application.
After the interview, follow up with a letter thanking the shop for the interview. In the letter include when the interview occurred and that from the information you received, that you are very interested in becoming a part of the organization (shop or dealership). Also include contact information such as your cell phone number and e-mail address so the service manager can easily get in contact with you. A quick review of your skills and talent will also be helpful to the shop owner or service manager.
ACCEPTING EMPLOYMENT When a job is offered, there will likely be some paperwork that needs to be filled out and decisions made. Some of the requested information could include:
Social security number (social insurance number in Canada)
W-4 tax withholding form
Emergency contact people
Retirement plan selection (This is usually given to you to study and return at a later date.)
Other information which may be unique to the shop or dealership
After accepting the employment position, be sure to determine exactly what day and time you should report to work and try to determine where your tools should be placed. Most places will show you around and introduce you to others you will work with.
TECHNICIAN PAY METHODS THE INTERVIEW When meeting for the job interview, be sure to dress appropriately for the position. For example, a suit and tie would not be appropriate for an interview for a service technician position. However, the following may be a helpful guide:
Wear shoes that are not sneakers and be sure they are clean
Wear slacks, not jeans
Wear a shirt with a collar
Do not wear a hat
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STRAIGHT-TIME PAY METHODS
When the particular service or repair is not covered or mentioned in a flat-rate guide, it is common practice for the technician to clock-in and use the actual time spent on the repair as a basis for payment. The technician uses a flat-rate time ticket and a time clock to record the actual time. Being paid for the actual time spent is often called straight time or clock time. Difficult engine performance repairs are often calculated using the technician’s straight time.
FLAT-RATE PAY METHODS
Beginning service technicians are usually paid by the hour. The hourly rate can vary greatly
depending on the experience of the technician and type of work being performed. Most experienced service technicians are paid by a method called flat-rate. The flat-rate method of pay is also called incentive or commission pay. “Flat-rate” means that the technician is paid a set amount of time (flat-rate) for every service operation. The amount of time allocated is published in a flat-rate manual. For example, if a bumper requires replacement, the flat-rate manual may call for 1.0 hour (time is always expressed in tenths of an hour). Each hour has 60 minutes. Each tenth of an hour is 1/10 of 60 or 6 minutes.
slow time of year, maybe the technician will only have the opportunity to “turn” 20 hours per week. So it is not really the pay rate that determines what a technician will earn but rather a combination of all of the following:
Pay rate
Number of service repairs performed
Skill and speed of the service technician
Type of service work (a routine brake service may be completed faster and easier than a difficult engine performance problem)
0.1 hour ⫽ 6 minutes 0.2 hour ⫽ 12 minutes 0.3 hour ⫽ 18 minutes 0.4 hour ⫽ 24 minutes
A service technician earns more at a busy dealership with a lower pay rate than at a smaller or less busy dealership with a higher pay rate.
0.5 hour ⫽ 30 minutes 0.6 hour ⫽ 36 minutes 0.7 hour ⫽ 42 minutes 0.8 hour ⫽ 48 minutes
PAYROLL DEDUCTIONS
0.9 hour ⫽ 54 minutes 1.0 hour ⫽ 60 minutes Many service operations are greater than 1 hour and are expressed as such: 2.4 hours ⫽ 2 hours and 24 minutes 3.6 hours ⫽ 3 hours and 36 minutes The service technician would therefore get paid the flat-rate time regardless of how long it actually took to complete the job. Often, the technician can “beat flat-rate” by performing the operation in less time than the published time. It is therefore important that the technician not waste time and work efficiently to get paid the most for a day’s work. The technician also has to be careful to perform the service procedure correctly because if the job needs to be done again due to an error, the technician does the repair at no pay. Therefore, the technician needs to be fast and careful at the same time. The vehicle manufacturer determines the flat-rate for each labor operation by having a team of technicians perform the operation several times. The average of all of these times is often published as the allocated time. The flat-rate method was originally developed to determine a fair and equitable way to pay dealerships for covered warranty repairs. Because the labor rate differs throughout the country, a fixed dollar amount would not be fair compensation. However, if a time could be established for each operation, then the vehicle manufacturer could reimburse the dealership for the set number of hours multiplied by the labor rate approved for that dealership. For example, if the approved labor rate is $60.00 per hour and: Technician A performed 6.2 hours ⫻ $60.00 ⫽ $372.00 Technician B performed 4.8 hours ⫻ $60.00 ⫽ $288.00 The total paid to the dealership by the ⫽ $660.00 manufacturer This does not mean that the service technician gets paid $60.00 per hour. Sorry, no! This means that the dealership gets reimbursed for labor at the $60.00 per hour rate. The service technician usually gets paid a lot less than half of the total labor charge. Depending on the part of the country and the size of the dealership and community, the technician’s flat-rate per hour income can vary from $7.00 to $20.00 or more per flat-rate hour. Remember, a high pay rate ($20 for example) does not necessarily mean that the service technician will be earning $800.00 per week (40 hours ⫻ $20.00 per hour ⫽ $800.00). If the dealership is not busy or it is a
GROSS VERSUS NET COMPENSATION Most beginning technicians start by receiving a certain amount of money per hours worked. Gross earnings are the total amount you earned during the pay period. The paycheck you receive will be for an amount called net earnings. Taxes and deductions that are taken from your paycheck may include all or most of the following:
Federal income tax
State income tax (not all states)
Social Security taxes (labeled FICA, which stands for Federal Insurance Contribution Act)
Health/dental/eye insurance deductions
In addition to the above, uniform costs, savings plan deductions, parts account deductions, as well as weekly payments for tools, may also reduce the amount of your net or “take-home” pay.
RETIREMENT INFORMATION AND PAYMENTS Some shops or dealerships offer some retirement savings plan but the most commonly used is an employer-sponsored 401(k) account named after a section of the U.S. Internal Revenue Code. A 401(k) account allows a worker to save for retirement while deferring taxes on the saved money and earnings until withdrawal. Most 401(k) plans allow the employer to select from stock mutual funds or other investments. A 401(k) retirement plan offers two advantages compared to a simple savings account.
The contributions (money deposited into the account) are tax deferred. The amount will increase due to interest and no taxes are due until the money is withdrawn.
Many employers provide matching contributions to your 401(k) account which can range from 0% (no matching contributions) to 100%.
The savings really add up over time. For example, if you start saving at age 25 and your income averages $3,000 per month ($36,000 per year) and you contribute 6% of your pay and the employer contributes 3%, after 40 years at age 65, the account will be worth $1,700,000 (one million, seven hundred thousand dollars) assuming a 10% average return. In retirement, most experts agree that 4% of the total can be withdrawn each year and not reduce the capital investment. Four percent of $1,700,000 is $68,000 per year or over $5,600 per month every month for the rest of your life.
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TECH TIP
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FREQUENTLY ASKED QUESTION
Hourly Rate to Annual Income
Where Does All the Money Go?
To calculate the amount of income that will be earned using an hourly rate, do the following:
Money earned does seem to quickly disappear. For example, if a soft drink and a bag of chips were purchased every day at work for $2.50, this amounts to $12.50 per week or $50 per month, which is $600 per year. Use the following chart to see where the money goes.
Multiply the hourly rate times 2 and then times 1000. For example: $10 per hour ⫻ 2 ⫻ 1000 ⫽ $20,000 per year. This easy-to-use formula assumes working eight hours an day, five days a week for 50 weeks (instead of 52 weeks in the year). The reverse can also be easily calculated: Divide the yearly income by 2 and then by 1000 ⫽ hourly rate For example: $36,000 per year ⫼ 2 ⫽ $18,000 ⫼1000 ⫽ $18 per hour
Income Labor rate per hour ⫻ number of hours worked ⫽ Overtime pay, if applicable ⫽ Part-time work on weekends ⫽ TOTAL WEEKLY INCOME ⴝ Multiply by 4.3 to get the MONTHLY INCOME ⫽
______ ______ ______ ______ ______ ______ ______ ______ ______ ______ ______ ______ ______ ______ ______ ______ ______
Paid uniforms/cleaning
Vacation time
Update training (especially new vehicle dealerships)
Some sort of retirement (usually a contributing 401(k)) program
Monthly Expenses Car/truck payment ⫽ Rent/mortgage ⫽ Gasoline ⫽ Food (groceries) ⫽ Fast food or restaurants ⫽ Heat and electric (heat/air conditioning) ⫽ Water and sewer ⫽ Telephone (cell) ⫽ Cable TV/internet access ⫽ Clothing (including cleaning) ⫽ Credit card payment ⫽
Health and dental insurance (usually not fully paid)
TOTAL MONTHLY EXPENSES ⴝ
Discounts on parts and vehicles purchased at the dealership or shop
ADDITIONAL SERVICE TECHNICIAN BENEFITS
Many larger dealerships and service facilities often offer some or all of the following:
Not all service facilities offer all of these additional benefits.
HOUSING AND LIVING EXPENSES As a general guideline, housing expenses such as rent or a mortgage payment should not exceed 30% of the gross monthly income. For example, Ten dollars per hour times 40 hours per week ⫽ $400 per week times 4 weeks in a month ⫽ $1600 per month. Thirty percent of $1600 is $480 per month for rent or a mortgage payment. A vehicle payment should not exceed 25% of the gross earnings. In the example where the pay was $10 per hour, the maximum recommended vehicle payment should be $400 per month.
BECOMING A SHOP OWNER Many service technicians want to start and operate their own shop. Becoming a shop owner results in handling many non-automotiverelated duties that some technicians do not feel qualified to handle, including:
Handling customers
Ordering and paying for shop equipment and supplies
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Hopefully, the total income is more than the total expenses!
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FREQUENTLY ASKED QUESTION
Employee or Contract Labor? Most shops and dealerships hire service technicians as employees. However, some shops or businesses will pay a technician for services performed on a contract basis. This means that they are not hiring you as an employee, but simply paying for a service similar to having a plumber repair a toilet. The plumber is performing a service and is paid for the job rather than as an employee of the shop. An employer/employee relationship exists if the shop meets two factors: 1. Direction—This means that the employer can direct the technician to report to work to perform service work. 2. Control—This means that the employer can direct the hours and days when the work is to be performed and at the employer’s location. A contract labor association exists if the repairs are performed without both direction and control of the shop. If a contract labor basis is established, then no taxes are withheld. It is then the responsibility of the technician to make the necessary and required general tax payments and pay all taxes on time.
Bookkeeping, including payroll
Budgeting for and paying for garage owner’s insurance and workers’ compensation
Paying rent, as well as heat/air-conditioning bills
Advertising expenses
Hiring and firing employees
TECH TIP Find Three Key People An entrepreneur is a person who organizes and manages their own business assuming the risk for the sake of a profit. Many service technicians have the desire to own their own repair facility. The wise business owner (entrepreneur) seeks the advice of the following people when starting and operating their own business. 1. Attorney (lawyer) —This professional will help guide you to make sure that your employees and your customers are protected by the laws of your community, state, and federal regulations. 2. Accountant —This professional will help you with the journals and records that must be kept by all businesses and to help with elements such as payroll taxes, unemployment taxes, and workmen’s compensation that all businesses have to pay. 3. Insurance Agent —This professional will help you select the coverage needed to protect you and your business from major losses.
REVIEW QUESTIONS 1. What facts should be included on the resume?
4. What taxes are usually withheld from a paycheck?
2. What are five interviewing tips?
5. What are five duties of a shop owner?
3. What is the difference between gross pay and net pay?
CHAPTER QUIZ 1. A resume should be how many pages long? a. 1 b. 2 c. 3 d. 4 or more 2. What personal information should not be included on the resume? a. Address b. Cell or telephone number c. Age d. Work experience 3. Why is having a good driving record good for the shop? a. Allows the use of a company vehicle b. Lowers insurance costs c. Allows you to drive customers’ vehicles d. Permits you to use your vehicle to get parts 4. Which is not recommended during an interview? a. Wear shoes that are not sneakers b. Wear a shirt with a collar c. Have clean hair d. Wear jeans 5. During an interview, try to ________. a. Show enthusiasm b. Explain your work experience c. State your willingness to work d. All of the above
6. Ten dollars per hour is about how much income per year? a. $20,000 c. $30,000 b. $25,000 d. $35,000 7. One of the deductions from a paycheck is for Social Security. This item is usually shown on the pay stub as ________. a. Social Security b. SSA c. FICA d. U.S. government deduction 8. Technician A says that the net pay amount is usually higher than the gross pay amount. Technician B says that the gross pay amount is usually higher than the net pay. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 9. A beginning service technician earns $400 per week. How much should the technician spend on a vehicle payment? a. $400 per month c. $800 per month b. $500 per month d. $1000 per month 10. Which activity does not allow a person to perform any work while at the shop? a. Cooperative education program b. Apprenticeship program c. Job shadowing d. Part-time employment
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chapter
4
WORKING AS A PROFESSIONAL SERVICE TECHNICIAN
OBJECTIVES: After studying Chapter 4, the reader will be able to: • Discuss how to start a new job. • Describe the advantages of having a mentor. • Explain how a mentor can improve on-the-job learning. • Discuss the role of the trainee with a mentor. • Explain formal and informal evaluations. • Describe the role of a service technician. • Explain how the flat-rate pay plan works. • Describe the type and pricing of parts. KEY TERMS: Advisor 31 • Advocate 31 • Aftermarket parts 29 • Coach 30 • Core 29 • Core charge 29 • Counselor 30 • Critical thinking 31 • Customer pay (CP) 28 • Flagging 29 • Formal evaluation 32 • Informal evaluation 32 • Jobber 29 • Mentor 30 • Original equipment (OE) 29 • Rebuilt 30 • Remove and inspect (R & I) 29 • Remove and replace (R & R) 29 • Renewal parts 29 • Repair order (RO) 27 • Role model 31 • Service bay 27 • Stall 27 • Teacher 30 • Three Cs (concern, cause, correction) 27 • Trainee 30 • Warehouse distributor 29
TECH TIP
PROFESSIONALISM
Clean Clothes Are a Must Professionalism and personal credibility are important and can determine success as a service technician or as a customer service provider. A true professional does the following on a regular basis.
Anyone who meets the public in any business must not only be dressed appropriately, but the clothing should be clean. Service advisors and others that greet the public should also be sure that their shoes are shined. Dull, dirty, or scuffed shoes or messy appearance reflects an unprofessional look.
1. Practice consistency. Be positive, professional, and warm at all times. 2. Keep your word. Follow through with the commitments that you make. People will not have faith in you if you break your promises. 3. Develop technical expertise. Become very knowledgeable about the vehicles being serviced. Attend regular update training classes to keep up with the latest technical information and equipment. 4. Become a teammate with your co-workers. Working successfully with others shows that you have common goals and can benefit from the specific skills of others. 5. Be accountable. Practice honesty all of the time, admit mistakes, and take responsibility for actions. Apologize if you are wrong.
ETHICS
Ethics are a set of principles that govern the conduct of an individual or group. Sometimes ethical decisions are easy to recognize and are perceived as popular choices of behavior by the people around us. At other times the spectrum of potential choices falls into gray areas in which the “right” or “wrong” course of action is difficult or nearly impossible to identify. When faced with an ethically challenging situation, ask yourself the following questions:
Is it legal? (Is it against local, state, or federal laws?)
Is it fair? (Is it harmful to me or to others?)
How do I feel about it? (Is it against the teachings of my parents or my religion?)
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Would the court of public opinion find my behavior incorrect? (Would it disappoint my family?)
Am I fearful of what those I trust would say about my actions? (Would I be hurt or upset if someone did this to me?)
The above questions can be quite revealing when attempting to choose an ethical course of action.
COMMUNICATIONS The five main methods of communication used in effective customer service interaction include listening, talking, nonverbal communications, reading, and writing.
LISTENING
Active listening is the ability to hear and understand what the speaker is saying. To listen to your customers or other technicians is to show them that you care about and respect their questions and concerns. It is not easy to be a good listener; it takes practice and dedication to improve your listening techniques. Listening is a skill that must continuously be developed. Several barriers to good listening exist. A listener may be distracted from what is being said, have a closed mind to the speaker
TECH TIP Never Use Profanity Regardless of the situation, a true professional never resorts to the use of profanity. If tensions are high and the discussion becomes heated, try to defuse the situation by turning the situation over to someone else.
and the message, won’t stop talking, or is lazy and unwilling to make the commitment to be a good listener. Listening requires the listener to stop talking and to hear what the speaker is saying. It has been said that humans were given two ears and one mouth because we are supposed to listen twice as much as we speak. The best way to keep your mind focused on the speaker and to avoid becoming distracted is to pay attention. We can think about 10 times faster than we can speak, so frequently we have processed what speakers have said and are waiting for them to catch up with us. By focusing on speakers and on what is being said we are less likely to miss the messages being delivered. Putting that into practice is not as easy as it sounds. A good listener does the following:
Focuses on the speaker and what is being said.
Looks at the speaker and makes eye contact when possible.
Listens with an open mind.
Rephrases what was said to clarify that the intended message is understood.
A good listener knows the joy of sharing and communicating with others. Work to become the best listener you can be.
TALKING Talking means speaking, using words and terminology that others can comprehend. Eye contact is always important when we are communicating with others. Eye contact is allowing our eyes to make visual contact with someone else’s. In our culture, eye contact conveys sincerity and interest. Avoiding eye contact may suggest a lack of concern or lack of honesty. Customers may perceive that a customer service provider is not interested in what they are saying if they do not periodically make eye contact with the customer. When dealing with people from other cultures, customer service providers should be aware of cultural differences. In many other cultures eye avoidance is a sign of respect. Be sensitive to others but use eye contact whenever possible.
FIGURE 4–1 When answering the telephone, be sure to have paper and pen or pencil handy to record the customer information.
TECH TIP Always Have Paper and a Pen When on the Telephone When talking to a customer, whether in person or on the telephone, have paper and a pencil or pen to record the necessary information. In this case, the customer service representative at a dealer is using a preprinted form to record the service procedures to be performed on a customer’s vehicle while talking on the phone. SEE FIGURE 4–1.
1. Ask questions, which would require them to pay attention plus it shows that you are interested in what they think. 2. Give the customer options rather than just ask them what they want such as saying “would you prefer to have this work done all at the same time or spread out over several weeks?”
TELEPHONE COMMUNICATION A large percentage of customers make first contact with a shop or dealer service department by telephone. Service technicians normally do not talk to customers directly but may be asked to help clarify a repair or a service procedure. Some suggestions when talking on the telephone include:
Use proper titles for the people with whom you communicate. If in doubt about whether to use a first name, call the person by the more formal Mr. or Ms. If they prefer the more informal first name, they will say so. It is better to be a little too formal than overly familiar.
Thank people for calling. “Thank you” is the most powerful phrase in human relations and it reassures customers that you are interested in serving.
Try to avoid technical terms and abbreviations such as EGR and other terms commonly used in the trade but will not be understood by the customer. Try to phrase the technical description by saying that you replaced or serviced a part in the emission control system and include the entire name of the part such as the “exhaust gas recirculation valve.”
Keep your comments positive and focused toward solving the problem or concern.
NONVERBAL COMMUNICATION
The tone and inflection of the voice, facial expressions, posture, hand movements, and eye contact are all forms of nonverbal communications. These nonverbal indicators can contradict the message conveyed through another method of communication. Nonverbal communication includes body posture such as having the arms crossed. When a person crosses their arms, or looks at other things rather than paying attention to what you are discussing, these actions could indicate one of several things including: 1. They are not interested in what you are saying 2. They don’t believe what you are saying 3. They are not listening
If this type of nonverbal communication is noticed, there are several things that could be done to overcome this barrier including:
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TECH TIP Use Internet Translation If the customer is non-English speaking, type the information into a text document and search for a translation on the Internet. Give the copy of the translated document to the customer. The customer request could also be translated into English if needed to help the shop understand exactly what the customer is requesting and needs.
TECH TIP Google Is Your Friend
FIGURE 4–2 If you smile while talking on the telephone, your attitude will be transmitted to the customer.
If unsure as to how something works or if you need more detailed information about something, go to www.google .com® and search for the topic. Using the Internet can help with locating hard-to-find facts and can even be used to help with a service procedure that you have not done before. For a link to all factory service information, go to the Web site of National Automotive Service Task Force at www.nastf.org. Look at the work scheduled for the next day and try to determine as much about the job as possible so you can be prepared the next day to tackle the procedure. Using the International Automotive Technicians Network at www.iatn.net is also very helpful for technical information and can help pin down hard-to-find problems.
TECH TIP Smile While You Talk If you smile while talking on the telephone, your voice will reflect a positive and helpful attitude, which customers or vendors will easily recognize over the telephone. SEE FIGURE 4–2.
Avoid saying anything that makes people or your shop look unprofessional or uncaring. When dealing with customers, some words are more positive and appropriate to use. Some customer service providers find it helpful to list words to use and words to avoid on a card so that it is available for easy reference.
Speak clearly and distinctly. Hold the telephone mouthpiece about a half-inch from your lips. Speak naturally and comfortably. Talk to your caller as you would to a friend.
Move to a quiet area if background noise level is high.
service information that the wiring connector was “adjacent to the coolant reservoir.” The technician did not understand what the word adjacent meant and found out from another technician that it meant “next or close to.” If reading a note from a customer written in another language you do not understand try to ask if someone else in the shop can read it for you.
WRITING
Writing is communicating by using the written word so that others can understand the intended message. Service technicians are required to document the work that was performed on a vehicle. For some technicians this is the most difficult part of the service. If writing, be sure it is legible and if not, then print all messages and information. Writing or typing in the description of the steps performed during the diagnosis and repair of the vehicle should be worded as if the technician is talking to the customer. For example, if a coolant leak was repaired by replacing the water pump the technician should write out the following steps and operations on the work order:
WHAT HAPPENS THE FIRST DAY? The first day on the job, someone, usually the shop owner or shop foreman, should:
Introduce the new technician to key people at the shop.
1. Visually verified coolant leaking.
2. Performed a pressure test of the cooling system and located the leak as coming from the water pump.
Show the new technician the facility, parking, rules, and regulations of the organization.
Establish the new technician’s work area.
Ask questions of the new technician regarding their skills and talents.
3. Replaced the water pump and added new coolant and bled the system of trapped air. 4. Pressure tested the cooling system to verify that the leak was corrected—no leaks found.
READING
Reading means the ability to read and comprehend the written word. All service technicians need to be able to read, understand, and follow written instructions and repair procedures. If some words are not understood use a dictionary or ask another technician for help. For example, a beginning technician read in the
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The shop owner or foreman should:
Review the training tasks that were completed in school.
Try to direct work to the new technician that covers the new training material.
The first day on the job the beginning technician should:
Smile and ask questions if needed to clarify procedures and regulations.
TECH TIP
TECH TIP
Don’t Touch Other Technician’s Tools
If Late—Call
A beginning technician seldom has all of the tools needed to perform all of the service and repair tasks. A technician’s tools are very important. If a tool needs to be borrowed, the beginning technician should ask for permission to borrow a tool. Then when the tool is returned , it should be clean and replaced back exactly where the technician asks for it to be returned.
When running late, you may know that you will be just a few minutes late but your boss does not how late you will be. If you are going to be late, even by a few minutes, call the shop and let them know. This does not eliminate your being late from your record, but does demonstrate your concern to your service manager and other technicians who are counting on you to being on time to work every day.
TECH TIP
TECH TIP Regulated Terms to Use
Ask Me about This
In some states or areas where automotive service is regulated, such as in California or Michigan, it is important that the term used to describe a labor operation is the term defined by the state agency. This means that some terms used in parts and time guides may not be the same terms used by the state. Always check that the terms used are in compliance with all regulations. Some terms that could be affected include rebuild, repair, overhaul, inspection and R & R (remove and replace), and safety inspection.
A good service advisor will document what the customer wants done on the work order. However, there are times when the explanation and description would take too long and too much space to be practical. In these cases, the wise service advisor simply states on the work order for the service technician to see the service advisor to discuss the situation. The service advisor can write the basic request to document what is needed.
Be prepared to take and pass a drug test.
Assure the service manager or shop owner that you are serious about a career as an automotive technician.
A work order, also called a repair order or RO is assigned to a technician who is best qualified to perform the work. The technician gets the keys and drives the vehicle to an assigned service bay (also called a stall), performs the proper diagnosis, gets the necessary parts from the parts department, and completes the repair. After the service work has been performed, the service technician should then fill out the work order and describe what work was performed. These are called the “three Cs.” 1. Concern—Write on the work order what was done to confirm the customer’s concern. For example, “Drove the vehicle at highway speed and verified a vibration.” 2. Cause—The service technician should write the cause of the problem. For example, “Used a scan tool and discovered that cylinder #3 was misfiring.” 3. Correction—The service technician should write what was done to correct the problem. For example, “Removed the spark plug wire from cylinder number three and by visual inspection found that the boot had been arcing to the cylinder head. Replaced the spark plug wire and verified that the misfire was corrected.”
DUTIES OF A SERVICE TECHNICIAN READING THE WORK ORDER
A work order is selected or assigned to a service technician who then performs the listed tasks. The work order should be written so that the technician knows
exactly what needs to be done. However, if there is any doubt, the technician should clarify the needed task with the service advisor or the person who spoke to the customer.
TALKING TO CUSTOMERS The typical service technician usually does not talk directly to a customer except in some smaller shops. However, there may be causes where the technician will be asked to clarify a procedure or repair to a customer. Many technicians do not like to talk to the customers and fear that they may say too much or not enough. If a technician is asked to talk to a customer, try to keep the discussion to the following without being too technical.
The service technician should repeat the original concern. This is to simply verify to the customer and the technician the goal of the service or repair.
The cause of the fault should be mentioned. If further diagnostic steps needed to find the cause are requested, discuss the steps followed and the equipment or tools used.
Discuss what was done to solve the concern, including what part or parts were replaced. This step may also include what other service operations were needed to complete the repair, such as reprogramming the computer.
NOTE: If the customer speaks a foreign language that you do not understand, excuse yourself and locate someone in the shop who can assist you with communicating with the customer. Avoid using slang or abbreviation of technical terms. Ask the person if they understand and be willing to restate, if needed, until the situation is understood. This can often be difficult if discussing technical situations to persons of another language or culture.
ESTIMATING A REPAIR
Sometimes a service technician is asked to help create an estimate for the customer. It is usually the responsibility of the service advisor or shop owner to create estiates.
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TECH TIP Car, Truck, or Vehicle?
What Can a Service Technician Do to Earn More Money?
When discussing a vehicle with a customer, it is best to avoid creating problems. For example, if a technician asked about a customer’s “car,” the customer could become concerned because they drive a truck and many owners of trucks do not want their vehicle called a car. Use of the term “vehicle,” a generic term, is often recommended when talking to customers to avoid possible concerns.
Because service technicians are paid on a commission basis (flat-rate), the more work that is completed, the more hours the technician can “turn.” Therefore, to earn the most money, the service technician could do the following to increase the amount of work performed: • Keep up-to-date and learn the latest technical information • Practice good habits that help avoid errors or incomplete repairs • Learn from experienced and successful fellow technicians and try to approach the repair the same way the successful technician does • Purchase the proper tools to do the work efficiently
The technician may be helpful by pointing out all of the operations that need to be performed to achieve a repair. The estimate for a repair includes:
Parts needed—This list would also include any gaskets and/ or supplies needed. The technician can help identify if extra supplies may be needed.
Labor—A published time guide is usually used but many times options such as rear air conditioning or four-wheel drive may add substantial time to the operation. The technician can help with the estimate by making sure that the options are pointed out to the service advisor or shop owner.
DOCUMENTING THE WORK ORDER The service technician must document the work order. This means that the service technician must write (or type) what all was done to the vehicle including documenting defective components or conditions that were found in the course of the diagnosis. The documentation is often called “telling the story” and should include the following:
The test equipment used to diagnose the problem. For example: Used a Tech 2 scan tool to retrieve P0300 random misfire diagnostic trouble code.
Used a digital multimeter to determine a spark plug wire was defective.
List what parts or service operations were performed. For example: Replaced the spark plug wire on cylinder number 3. Used a scan tool to clear the diagnostic trouble codes and verify that the engine is operating correctly.
FOLLOWING RECOMMENDED PROCEDURES All service technicians should follow the diagnostic and service procedures specified by the vehicle manufacturer. Following service information procedures includes the following:
Follow and document the diagnostic procedure. Writing down the test results helps the customer see all that was involved in the procedure and creates the proper paper trail for future reference, if needed.
Follow the recommended removal and reinstallation (R & R) procedures. This step helps prevent the possibility of doing harm to the vehicle if an alternative method is attempted.
Always torque fasteners to factory specifications. This step is very important because under- or overtightened fasteners can cause problems that were not present until after the repair. The wise technician will document torque specifications on the work order.
CUSTOMER PAY Customer pay (CP) means that the customer will be paying for the service work at a dealership rather than
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FREQUENTLY ASKED QUESTION
NOTE: This does not mean that every technician needs to purchase all possible tools. Purchase only those tools that you know you will need and use.
the warranty. Often the same factory flat-rate number of hours is used to calculate the technician’s pay, but customer pay often pays the service technician at a higher rate. For example, a service technician earning $15.00 per flat-rate hour for warranty work may be paid $18.00 per hour for customer-pay work. Obviously, service technicians prefer to work on vehicles that require customer-pay service work rather than factory-warranty service work.
NONDEALERSHIP FLAT-RATE Technicians who work for independent service facilities or at other nondealership locations use one or both of the following to set rates of pay:
Mitchell, Motors, or Chilton parts and time guides
Alldata, Shop-Key, Car-Quest, Auto Value, Mitchell, AC Delco, or other shop management software program.
These guides contain service operation and flat-rate times. Generally, these are about 20% higher (longer) than those specified by the factory flat-rate to compensate for rust or corrosion and other factors of time and mileage that often lengthen the time necessary to complete a repair. Again, the service technician is usually paid a dollar amount per flat-rate hour based on one of these aftermarket flat-rate guides. The guides also provide a list price for the parts for each vehicle. This information allows the service advisor to accurately estimate the total cost of the repair.
FLAGGING A WORK ORDER When a service technician completes a service procedure or repair, a sticker or notification on the work order indicates the following:
Technician number (number rather than a name is often used not only to shorten the identification but also to shield the actual identity of the technician from the customer)
Work order number
PARTS REPLACEMENT Parts replacement is often called R & R, meaning remove and replace. NOTE: R & R can also mean remove and repair, but this meaning is generally not used as much now as it used to be when components such as starters and air-conditioning compressors were repaired rather than replaced as an assembly.
FIGURE 4–3 Note the skill levels of the technician and the extra time that should be added if work is being performed on a vehicle that has excessive rust or other factors as stated in the time guide.
TECH TIP Technician Skill Level and Severe Service Most aftermarket service information includes a guideline for the relative level of the technician’s skill required to perform the listed service procedures. These include: A Highly skilled and experienced technician B Skilled technician who is capable of performing diagnosis of vehicle systems C Semi-skilled technician who is capable of performing routine service work without direct supervision Many time guides provide additional time for vehicles that may be excessively rusted due to climate conditions or have been subjected to abuse. Be sure to quote the higher rate if any of these conditions are present on the customer’s vehicle. SEE FIGURE 4–3.
Actual clock time from a time clock record for certain jobs as needed.
Amount of time allocated to the repair expressed in hours and tenths of an hour
The application of the service technician’s sticker to the back of the work order or completing the details of the repair into the electronic service record is called flagging the work order. NOTE: The actual assignment of the time is often done by another person at the dealership or service facility. This procedure assures that the correct number of hours is posted to the work order and to the technician’s ticket.
SUBLET REPAIRS Often a repair (or a part of a repair) is performed by another person or company outside of the dealership or service facility. For example, an engine needing repair that also has a defective or leaking radiator would be repaired by the original repair facility, but the radiator may be sent to a specialty radiator repair shop. The radiator repair cost is then entered on the work order as a sublet repair.
R & I is often used to indicate remove and inspect to check a component for damage. The old replaced part is often returned for remanufacturing and is called a core. A core charge is often charged by parts stores when a new (or remanufactured) part is purchased. This core charge usually represents the value of the old component. Because it is needed by the remanufacturer as a starting point for the remanufacturing process, the core charge is also an incentive to return the old part for credit (or refund) of the core charge. NOTE: Most parts stores today require that all cores be returned in the original boxes. Be sure to place the defective part into the same box that was used for the new or remanufactured part to be sure that the shop gets the proper credit for the core.
ORIGINAL EQUIPMENT PARTS
Parts at a new vehicle dealership come either directly from the vehicle manufacturer or a regional dealership. If one dealership purchases from another dealership, the cost of the part is higher, but no waiting is required. If a dealership orders a part from the manufacturer directly, the cost is lower, but there is often a 7- to 10-day waiting period. Original equipment parts, abbreviated OE, are generally of the highest quality because they have to meet performance and durability standards not required of replacement parts manufacturers. NOTE: Many service technicians will use only OE parts for certain critical systems such as fuel injection and ignition system components because, in their experience, even though the price is often higher, the extra quality seems to be worth the cost not only to the owner of the vehicle but also to the service technician who does not have to worry about having to replace the same part twice.
AFTERMARKET PARTS Parts manufactured to be sold for use after the vehicle is made are often referred to as aftermarket parts or renewal parts. Most aftermarket parts are sold at automotive parts stores or jobbers. A jobber or parts retailer usually gets parts from a large regional warehouse distributor. The warehouse distributor can either purchase parts directly from the manufacturer or from an even larger central warehouse. Because each business needs to make a profit (typically, 35%), the cost to the end user may not be lower than it is for the same part purchased at a dealership (two-step process instead of the typical three-step process) even though it costs more to manufacture the original equipment part. To determine what a 35% margin increase is for any product, simply divide the cost by 0.65. To illustrate how this works, compare the end cost of a part (part A) from a dealership and a parts store.
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Retail Parts Store
New Vehicle Dealership
Manufacturer’s selling price $17.00
Manufacturer’s selling price $25.00
Warehouse distributor’s selling price $26.15 ($17.00 0.65 $26.15)
Parts department selling price $38.46 ($25.00 0.65 $38.46)
TECH TIP Work Habit Hints The following statements reflect the expectations of service managers or shop owners for their technicians: 1. Report to work every day on time. Being several minutes early every day is an easy way to show your service manager and fellow technicians that you are serious about your job and career. 2. If you must be late or absent, call your service manager as soon as possible. 3. Keep busy. If not assigned to a specific job, ask what activities the service manager or supervisor wants you to do. 4. Report any mistakes or accidents immediately to your supervisor or team leader. Never allow a customer to be the first to discover a mistake. 5. Never lie to your employer or to a customer. 6. Always return any borrowed tools as soon as you are done with them and in clean condition. Show the person you borrowed the tools from that you are returning them to the toolbox or workbench. 7. Keep your work area neat and orderly. 8. Always use fender covers when working under the hood. 9. Double-check your work to be sure that everything is correct. a. Remember: “If you are forcing something, you are probably doing something wrong.” b. Ask for help if unclear as to what to do or how to do it. 10. Do not smoke in a customer’s vehicle. 11. Avoid profanity. 12. DO NOT TOUCH THE RADIO! If the radio is turned on and prevents you from hearing noises, turn the volume down. Try to return the vehicle to the owner with the radio at the same volume as originally set.
Retail store selling price $40.23 ($26.15 0.65 $40.23)
NOTE: The cost of the part to the customer where service work is performed is increased about 35% over the base cost of the part. For example, a part that cost the repair facility $40.23 will be billed to the customer at about $61.00. The retail service customer at the dealer may pay $59.17 ($38.46 ⴜ 0.65 ⴝ $59.17).
NEW VERSUS REMANUFACTURED PARTS
New parts are manufactured from raw materials and have never been used on a vehicle. A remanufactured component (also called rebuilt) has been used on a vehicle until the component wore out or failed. A remanufacturer totally disassembles the component, cleans, machines, and performs all the necessary steps to restore the part to a “like new” look and function. If properly remanufactured, the component can be expected to deliver the same length of service as a new component part. The cost of a remanufactured component is often less than the cost of a new part. CAUTION: Do not always assume that a remanufactured component is less expensive than a new component. Due to the three-step distribution process, the final cost to the end user (you) may be close to the same!
USED PARTS
Used parts offer another alternative to either new or remanufactured parts. The cost of a used component is typically onehalf the cost of the component if purchased new. Wrecking and salvage yards use a Hollander manual that lists original equipment part numbers and cost and cross-references them to other parts that are the same.
NOTE: Some shops have a policy that requires employees to turn the radio off. 13. Keep yourself neatly groomed including: a. Shirttail tucked into pants (unless shirt is designed to be worn outside) b. Daily bathing and use of deodorant c. Clean hair, regular haircuts, and hair tied back if long d. Men: daily shave or keep beard and/or mustache neatly trimmed e. Women: makeup and jewelry kept to a minimum
WORKING WITH A MENTOR A mentor is a person at the job site who helps the beginning service technician, also called the trainee. The word mentor comes from Greek mythology. In Homer’s The Odyssey, Mentor was the faithful companion and friend of Ulysses (Odysseus), the King of Ithaca. Before Ulysses went to the Trojan Wars, he instructed Mentor to stay and take full charge of the royal household. This meant that Mentor had to be father figure, teacher, role model, counselor, trusted advisor, challenger, and encourager to the King’s son in order that he become a wise and good ruler. Therefore, a good definition of a mentor would be, “A highly qualified individual who is entrusted with the protection and development of an inexperienced technician.” A mentor therefore fulfills many roles, such as:
Teacher—helps teach information and procedures
Coach—has trainee practice service procedures
Counselor—concerned about, but not trained to offer advice on personal life decisions.
Advisor—helps with career-type decisions, such as what tools are needed
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Advocate (stands up for the trainee)—represents and helps the trainee’s concerns be expressed to others
Role model—presents a positive role model every day
QUALIFICATIONS OF A GOOD MENTOR
A good mentor should be assigned to a new technician. Qualifications of a good mentor include:
Trade proficiency—The person selected should be a highly skilled technician.
Good coaching/mentoring skills and techniques—The mentor has to have patience and be willing to help the trainee by explaining each step needed to complete a service procedure.
TECH TIP Adhere to the Times When starting a new job at a shop or dealership, be sure to ask about the following: • What time should I arrive at work? This may be different than the scheduled work starting time. For example, the work day could start at 8 a.m. but the shop owner or service manager may want all technicians to arrive and start to get ready to work at 7:50 a.m. • When is break time? Breaks may or may not be regularly scheduled and it is important for the beginning technician to know and adhere to break times. • When is lunch time? In some busy shops, the lunch period is staggered to be sure that some technicians are always available for work. Always be willing to adhere to the requested lunch period.
Leadership/role model—The mentor should take pride in being a professional service technician and have high ethical and professional standards.
Mentoring a trainee can be frustrating for an experienced technician. This occurs because the mentor needs to verify almost everything the trainee does until satisfied that competence has been achieved. Even very basic procedures need to be watched, such as hoisting the vehicle, changing the oil and oil filter, plus many other operations. As a result, the time taken to help the beginning technician will reduce the efficiency, and therefore, the pay of the mentor. However, after several weeks, the trainee can start helping the mentor, thereby increasing efficiency.
TEAMWORK TEAM BUILDING
A team is a group of individuals working together to achieve a common goal. Even shops or service departments that do not use a team system with a group of technicians is still a team. All members of the service department are really part of a team effort working together to achieve efficient vehicle service and customer satisfaction. The key to building a team that works together is selecting employees that are willing to work together. While the shop owner or service manager at a dealership has hiring authority, every technician should consider what is best for the entire group to help increase repeat business and satisfied customers.
focus efforts on improving your personal and professional life. Goals can include: Career, physical, family, education, financial and public service. There are many helpful web sites that can be used to help set and track progress toward achieving goals. The hardest part of any goal is to write it down. Until it is written down, a goal is not real.
BUSINESS MEETINGS
All service technicians attend business (shop) meetings. A good business meeting will have the following features: 1. An agenda (list of topics to be discussed) will be given out or displayed. 2. The meeting should start on time and end on time. 3. If someone is to give a report or be asked to do a project, this topic should be discussed with the designated person before the meeting to avoid that person from being surprised and made to feel uncomfortable. 4. The meeting should be held following the “Robert’s Rule of Order” guidelines. 5. Often meetings include others from inside or outside the company or shop, so try to look your best and smile to make the best impression.
ADVANCEMENT SKILLS The job of a service technician becomes more valuable to the shop or dealership if work can be accomplished quickly and without any mistakes. Therefore, being careful to avoid errors is the first consideration for any service technician. Then, with experience, the speed of accomplishing tasks can and will increase. More than speed is needed to become a master technician. It requires problem solving and critical thinking skills, too. While beginning technicians are usually not required to diagnose problems, troubleshooting skills are very important toward becoming a master technician. Most master technicians follow a plan which includes: 1. Always verify the customer concern. 2. Perform a thorough visual inspection and check for possible causes of the problem, including damage from road debris or accidents. 3. Use a scan tool and check for stored diagnostic trouble codes (DTCs). 4. Check service information for technical service bulletins (TSBs). 5. Check service information and follow all diagnostic trouble charts. 6. Locate and correct the root cause of the problem.
LEADERSHIP ROLES
As a technician gains experience, he or she often asks for guidance, not only for technical answers, but also for how to handle other issues in the shop, such as paperwork, use of aftermarket parts, and other issues. Therefore, the more experience the technician has, the more likely he or she will be placed in a leadership and role model position.
GOAL SETTING AND BUSINESS MEETINGS GOAL SETTING
The wise service technician sets goals to achieve during a career and life. The purpose of goal setting is to
7. Verify the repair and document the work order. The hardest part of the diagnostic process is to locate the root cause of the problem. The process of analyzing and evaluating information and making a conclusion is called critical thinking.
HOUSEKEEPING DUTIES A professional service technician is usually responsible for keeping his or her work area clean and tidy. Good housekeeping includes all of the following:
Clean floor—If coolant or oil is spilled on the floor during a repair procedure, it should be cleaned before starting another job.
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TECH TIP
TECH TIP Keeping “Things” off the Floor
Write It Down
To make cleaning easier and for a more professional shop appearance, keep only those items on the floor that have to be on the floor and find a place off the floor for all other items.
If a technician needs to have another technician finish a repair due to illness or some other reason, be sure to write down exactly what was done and what needs to be done. Verbal communication, while very effective, is often not a good way to explain multiple steps or processes. For example, the other technician could easily forget that the oil had not yet been added to the engine, which could cause a serious problem if the engine were to be started. If in doubt, write it down.
TECH TIP Look at the Shop from a Customer’s Point of View To determine if the shop and other technicians look professional, step outside and enter the shop through the same door as a customer. Now look around. Look at the shop and the other technicians. Does the shop give the appearance of a professional service facility? If not, try to improve the look by asking the shop owner or service manager to do the same thing in an attempt to create a more professional looking shop.
Tool box—Keep work area and tool box clean and organized.
Items kept off the floor—It is easy to allow parts and other items to be stored in and around the toolbox and in corners. However, having items on the floor makes keeping the area clean and neat looking very difficult.
Keep areas around exits and fire extinguishers clear. Do not store or place parts, boxes, or shop equipment, such as floor jacks and testers, near exits and fire extinguishers. This helps ensure that people can have easy access to exits or the fire extinguishers in the event of an emergency. Avoid spraying chemicals in the air. To help keep the air in the shop clean, keep the use of spray chemicals, such as brake cleaner, to a minimum and avoid spraying where it could result in affecting the air others breathe.
SELF-MANAGEMENT A professional service technician should try to maintain a professional appearance at all times. For example, if coolant or automatic transmission fluid (ATF) gets onto a shirt or pants, the wise technician would change into a clean uniform before working on another vehicle. Many shop owners and service managers recommend that shirttails always be tucked into pants to ensure a more professional appearance.
JOB EVALUATION In most jobs, there is an evaluation of performance. A beginning technician is not expected to perform at the same level as an experienced master technician but should be able to do the following:
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Follow instructions. The trainee should follow the instructions of the mentor or service manager. This includes making
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TECH TIP Don’t Cover Up Mistakes Everyone makes mistakes. While a damaged component or vehicle is never a good thing to have happen, the wise technician should notify the service manager or other person in charge as soon as a problem or accident occurs. Only then can work begin to correct the problem. If a mistake is hidden, eventually someone will learn about the error and then people will not think it was wise to ignore or to cover up the situation.
sure that the person is notified when the job has been completed and if there were any problems.
Do no harm. Avoid exerting a lot of force to door panels or other components to help avoid breaking clips or components. Always use the right tool for the job. For example, never use pliers to remove a bolt or nut, which could round off the flats of the fastener. Always think before acting, “Am I going to hurt something by doing this?”
Keep a neat and clean appearance. It is normal to get dirty while performing service work on a vehicle. However, after each job is completed or even during the repair, try to keep as clean as possible.
Ask that your work be checked. Even though the trainee thinks that the service or repair was done correctly, until confidence has been established, it is wise to ask to have all work double-checked.
CAUTION: Never allow a mistake to reach the customer. It is only a problem if it cannot be corrected.
FORMAL EVALUATION
The mentor and/or service manager may or may not conduct a written evaluation on a regular basis. If a written evaluation is performed, this is called a formal evaluation. A formal evaluation usually includes many points of discussion. See the sample evaluation form.
INFORMAL EVALUATION In many cases, a beginning technician’s activities are simply observed and noted, which is a type of informal evaluation. Both are usually done and both can influence the technician’s pay. NOTE: Most employees are fired from a job as the result of not being able to get along with others, rather than a lack of technical skills.
Technician Evaluation Please check one of the spaces to the left of each characteristic which best expresses your judgment of the technician: ATTITUDE-APPLICATION TO WORK _____outstanding in enthusiasm _____very interested and industrious _____average in diligence and interest _____somewhat indifferent _____definitely not interested
INITIATIVE _____proceeds well on his or her own _____proceeds independently at times _____does all assigned work _____hesitates _____must be pushed frequently
DEPENDABILITY _____completely dependable _____above average in dependability _____usually dependable _____sometimes neglectful or careless _____unreliable
RELATIONS WITH OTHERS _____exceptionally well accepted _____works well with others _____gets along satisfactorily _____has difficulty working with others _____works very poorly with others
QUALITY OF WORK _____excellent _____very good _____average _____below average _____very poor
QUANTITY OF WORK _____usually high output _____more than average _____normal amount _____below average _____low output, slow
MATURITY _____shows confidence _____has good self-assurance _____average maturity _____seldom assertive _____timid _____brash
JUDGMENT _____exceptionally mature _____above average _____usually makes the right decision _____often uses poor judgment
ABILITY TO LEARN _____learned work exceptionally well _____learned work readily _____average in understanding work _____rather slow in learning _____very slow to learn
ATTENDANCE _____regular _____irregular PUNCTUALITY _____regular _____irregular
REVIEW QUESTIONS 1. What factors are part of being a professional service technician?
5. A formal evaluation could include what items?
2. What is a mentor?
6. What are the three Cs?
3. What are the roles of a mentor?
7. What should be included on the work order after the repair has been completed?
4. What are the responsibilities the beginning technician has to the shop and/or mentor?
CHAPTER QUIZ 1. Professionalism includes which factor? a. Keeping your word b. Becoming a teammate with your co-workers c. Apologizing if you are wrong d. All of the above
2. Type of communications include ________. a. Verbal b. Written c. Nonverbal d. All of the above
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3. The three Cs include ________, ________, and ________. a. Correction, correct torque, and customer name b. Concern, cause, and correction c. Cause, cost, and caller name d. Captured data, cause, and cost (of the repair)
7. If running late, the wise technician should ________. a. Call the shop and let them know you will be late b. Speed up c. Call the shop and take the day off d. Stop and eat a good breakfast before going to the shop
4. When documenting the work order, what things should be listed? a. The test equipment used in the diagnosis b. The test procedure that was followed c. The parts that were replaced d. All of the above
8. Flat-rate pay means ________. a. The same pay (flat-rate) every week b. The same number of hours every week c. The technician is paid according to the job, not by the number of hours worked d. The technician is paid overtime
5. Technician A says that customer-pay rate is sometimes higher than the factory flat-rate. Technician B says that the factory flat-rate times are usually longer (given more time) compared to aftermarket flat-rate time guides. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 6. Housekeeping duties of a technician can include _________. a. Cleaning the floor b. Keeping the work area clean and organized c. Keeping items off the floor whenever possible d. All of the above
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9. Customer pay (CP) means ________. a. Customer pays for the repair or service b. Warranty does not pay for the repair or service c. The technician often gets paid more for each job d. All of the above 10. A mentor performs all of the following except ________. a. Helps guide diagnosis of a problem b. Signs paychecks c. Offers advice on how to do a job d. Advises on professional behavior
TECHNICIAN CERTIFICATION
OBJECTIVES: After studying Chapter 5, the reader will be able to: • Explain the requirements for becoming an ASE certified technician. • Describe the type of test questions asked on the certification tests. • Explain how to prepare to take the ASE certification tests. • Describe test taking skills needed to help pass the certification tests. • Explain how to register and take the ASE certification tests. KEY TERMS: Except-type questions 36 • ASE (National Institute for Automotive service Excellence) 34 • Distracter 35 • Experience-based questions 35 • IP certification 40 • Key 35 • Least-likely-type question 36 • ASE certified master 35 • Most-likely-type question 36 • Multiple-choice question 36 • Technician A and B question 36 • Work experience 35
AUTOMOBILE TECHNICIAN CERTIFICATION TESTS
WHAT AREAS OF VEHICLE SERVICE ARE COVERED BY THE ASE TESTS? Automobile test service areas include: A1 Engine Repair A2 Automatic Transmission/Transaxle
Even though individual franchises and companies often certify their own technicians, there is a nationally recognized certificate organization, the National Institute for Automotive Service Excellence, better known by its abbreviation, ASE. SEE FIGURE 5–1. ASE is a nonprofit association founded in 1972, and its main goal is to improve the quality of vehicle service through standardized testing and volunteer certification.
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A3 Manual Drive Train and Axles A4 Suspension and Steering A5 Brakes A6 Electrical/Electronic Systems A7 Heating and Air Conditioning A8 Engine Performance
for certification, except as noted below. If you have not previously provided work experience information, you will receive a Work Experience Report Form with your admission ticket. You must complete and return this form to receive a certificate. SUBSTITUTIONS FOR WORK EXPERIENCE. You may receive credit for up to one year of the two-year work experience requirement by substituting relevant formal training in one, or a combination, of the following: High School Training: Three full years of training, either in automobile/truck/school bus repair or in collision repair, refinishing, or damage estimating, may be substituted for one year of work experience. Post-High School Training: Two full years of post-high school training in a public or private trade school, technical institute, community or four-year college, or in an apprenticeship program may be counted as one year of work experience. Short Courses: For shorter periods of post-high school training, you may substitute two months of training for one month of work experience. You may receive full credit for the two-year work experience requirement with the following: Completion of Apprenticeship: Satisfactory completion of either a three- or four-year bona fide apprenticeship program.
ARE THERE ANY HANDS-ON ACTIVITIES ON THE ASE TEST?
FIGURE 5–1 The ASE logo. (Courtesy of ASE) If a technician takes and passes all eight of the automobile tests and has achieved two or more years of work experience, ASE will award the designation of ASE Certified Master Automobile Technician. Contact ASE for other certification areas.
HOW CAN I CONTACT ASE? ASE
Toll-free: 1-877-ASE-TECH (273-8324)
101 Blue Seal Drive, SE
1-703-669-6600
Suite 101
Web site: www.ase.com
Leesburg, VA 20175
No. All ASE tests are written using objective-type questions, meaning that you must select the correct answer from four possible alternatives.
WHO WRITES THE ASE QUESTIONS?
All ASE test questions are written by a panel of industry experts, educators, and experienced ASE certified service technicians. Each question is reviewed by the committee and it is checked for the following:
Technically accurate. All test questions use the correct terms and only test for vehicle manufacturer’s recommended service procedures. Slang is not used nor are any aftermarket accessories included on the ASE test.
Manufacturer neutral. All efforts are made to avoid using vehicle or procedures that are manufacturer specific such as to General Motors vehicles or to Toyotas. A service technician should feel comfortable about being able to answer the questions regardless of the type or brand of vehicle.
Logical answers. All effort is made to be sure that all answers (not just the correct answers) are possible. While this may seem to make the test tricky, it is designed to test for real knowledge of the subject.
Random answer. All efforts are made to be sure that the correct answers are not always the longest answer or that one letter, such as c, is not used more than any other letter.
Experience-based questions. The questions asked are generally not knowledge-based questions, but rather require experience to answer correctly. Specifications are not asked for, but instead a question as to what would most likely occur if the unit is out-of-specifications could be asked.
WHEN ARE THE TESTS GIVEN AND WHERE?
The ASE written tests are given at hundreds of test sites throughout the year for online testing. NOTE: ASE also offers tests at other times of the year electronically. Go to the ASE Web site for details. Deadline for registration is usually in late March for the May tests and in late September for the November tests. Consult the ASE registration booklet or Web site for details and locations of the test sites.
WHAT DO I HAVE TO DO TO REGISTER?
You can register
for the ASE tests in three ways: 1. Mail in the registration form that is in the registration booklet. 2. Register online at www.ase.com 3. Telephone at (866) 427-3273 Call ASE toll-free at 1-888-ASE-TEST or visit the Web site for details about cost and dates.
HOW MANY YEARS OF WORK EXPERIENCE ARE NEEDED? ASE requires that you have two or more years of full-time, hands-on working experience either as an automobile, truck, truck equipment, or school bus technician, engine machinist, or in collision repair, refinishing, or damage analysis and estimating
KEY AND DISTRACTER
The key is the correct answer. As part of the test writing sessions, the committee is asked to create other answers which sound feasible but are not correct. These incorrect answers are called distracters.
WHAT TYPES OF QUESTIONS ARE ASKED ON THE ASE TEST? All ASE test questions are objective. This means that there will not be questions where you will have to write an answer.
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Instead, all you have to do is select one of the four possible answers and place a mark in the correct place on the score sheet.
Multiple-choice questions. This type of question has one correct (or mostly correct) answer (called the key) and three incorrect answers. A multiple-choice question example: What part of an automotive engine does not move? a. b. c. d.
Example: Two technicians are discussing an engine that has lower than specified fuel pressure. Technician A says that the fuel pump could be the cause. Technician B says that the fuel pressure regulator could be the cause. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
Analysis: Is Technician A correct? The answer is yes because if the fuel pump was defective, the pump pressure could be lower than specified by the vehicle manufacturer. Is Technician B correct? The answer is yes because a stuck open regulator with a weak spring could be the cause of lower than specified fuel pressure. The correct answer is therefore c (Both Technicians A and B are correct).
Most-likely-type questions. This type of question asks which of the four possible items listed is the most likely to cause the problem or symptom. This type of question is often considered to be difficult because recent experience may lead you to answer the question incorrectly because even though it is possible, it is not the “most likely.” Example: Which of the items below is the most likely to cause blue exhaust at engine start? a. Valve stem seals b. Piston rings
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Except-type questions. ASE will sometimes use a question that includes answers that are all correct except one. You have to determine which of the four answers is not correct. Example: A radiator is being pressure tested using a hand-operated tester. This test will check for leaks in all except:
a. Radiator b. Heater core
Technician A only Technician B only Both Technicians A and B Neither Technician A nor B
The best way to answer this type of question is to carefully read the question and consider Technician A and Technician B answers to be solutions to a true or false question. If Technician A is correct, mark on the test by Technician A the letter T for true. (Yes, you can write on the test.) If Technician B is also correct, write the letter T for true by Technician B. Then mark c on your test score sheet, for both technicians are correct.
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The correct answer is a because valve stem seals are the most likely to cause this problem. Answer b is not correct because even though worn piston rings can cause the engine to burn oil and produce blue exhaust smoke, it is not the most likely cause of blue smoke at engine start. Answers c and d are not correct because even though these items could contribute to the engine burning oil and producing blue exhaust smoke, they are not the most likely.
Technician A and Technician B questions. This type of question is generally considered to be the most difficult according to service technicians who take the ASE test. A situation or condition is usually stated and two technicians (A and B) say what they think could be the correct answer and you must decide which technician is correct. a. b. c. d.
Analysis:
Piston Connecting rod Block Valve
The correct answer is c (block). This type of question asks for a specific answer. Answer a (piston), b (connecting rod), and d (valve) all move during normal engine operation. The best answer is c (block) because even though it may vibrate, it does not move as the other parts do.
c. Clogged PCV valve d. A stuck oil pump regulator valve
c. Water pump d. Evaporator
Analysis: The correct answer is d because the evaporator is not included in the cooling system and will not be pressurized during this test. Answers a (radiator), b (heater core), and c (water pump) are all being tested under pressure exerted on the cooling system by the pressure tester.
Least-likely-type questions. Another type of question asked on many ASE tests is a question that asks which of the following is least likely to be the cause of a problem or symptom. In other words, all of the answers are possible, but it is up to the reader to determine which answer is the least likely to be correct. Example: Which of the following is the least likely cause of low oil pressure?
a. Clogged oil pump screen b. Worn main bearing
c. Worn camshaft bearing d. Worn oil pump
Analysis: The correct answer is c because even though worn camshaft bearings can cause low oil pressure, the other answers are more likely to be the cause.
QUESTIONS OFTEN ASKED SHOULD I GUESS IF I DON’T KNOW THE ANSWER? Yes. ASE tests simply record the correct answers, and by guessing, you will have at least a 25% (1 out of 4) chance. If you leave the answer blank, it will be scored as being incorrect. Instead of guessing entirely, try to eliminate as many of the answers as possible as not being very likely. If you can eliminate two out of the four, you have increased your chance of guessing to 50% (two out of four). IS EACH TEST THE SAME EVERY TIME I TAKE IT?
No. ASE writes many questions for each area and selects from this “test bank” for each test session. You may see some of the same questions if you take the same test in the spring and then again in the fall, but you will also see many different questions.
TECH TIP Never Change an Answer Some research has shown that your first answer is most likely to be correct. It is human nature to read too much into the question rather than accept the question as it was written.
CAN I SKIP QUESTIONS I DON’T KNOW AND COME BACK TO ANSWER LATER? Yes. You may skip a question if you wish, but be sure to mark the question and return to answer the question later. It is often recommended to answer the question or guess and go on with the test so that you do not run out of time to go back over the questions.
one or more ASE tests. Therefore, it is wise to take as many tests as you can at each test session.
WILL I RECEIVE NOTICE OF WHICH QUESTIONS I MISSED? ASE sends out a summary of your test results, which shows how many questions you missed in each category, but not individual questions.
WILL ASE SEND ME THE CORRECT ANSWERS TO THE QUESTIONS I MISSED SO I WILL KNOW HOW TO ANSWER THEM IN THE FUTURE? No. ASE will not send you the answers to test questions.
TEST-TAKING TIPS HOW MUCH TIME DO I HAVE TO TAKE THE TESTS?
Each computer-based test will allow enough time for completion, usually between one and two hours for each test. The time allowed for each test is available on the ASE web site.
WILL I HAVE TO KNOW SPECIFICATIONS AND GAUGE READINGS? Yes and no. You will be asked the correct range for a particular component or operation and you must know about what the specification should be. Otherwise, the questions will state that the value is less than or greater than the allowable specification. The question will deal with how the service technician should proceed or what action should be taken.
CAN I TAKE A BREAK DURING THE TEST? Yes, you may use the restroom after receiving permission from the proctor of the test site. CAN I LEAVE EARLY IF I HAVE COMPLETED THE TEST(S)? Yes, you may leave quietly after you have completed the test(s). You must return the score sheet(s) and the test booklets as you leave.
HOW ARE THE TESTS SCORED?
The ASE tests are machine scored and the results tabulated by American College Testing (ACT).
WHAT PERCENTAGE DO I NEED TO ACHIEVE TO PASS THE ASE TEST? While there is no exact number of questions that must be answered correctly in each area, an analysis of the test results indicate that the percentage needed to pass varies from 61% to 69%. Therefore, in order to pass the Engine Repair (A1) ASE certification test, you will have to answer about 39 questions correct out of 60. In other words, you can miss about 21 questions and still pass.
WHAT HAPPENS IF I DO NOT PASS? DO I HAVE TO WAIT A YEAR BEFORE TRYING AGAIN? No. If you fail to achieve a passing score on any ASE test, you can take the test again at the next testing session (in May or November).
DO I HAVE TO PAY ANOTHER REGISTRATION FEE IF I ALREADY PAID IT ONCE? Yes. The registration fee is due at every test session in May or November whether you select to take
START NOW Even if you have been working on vehicles for a long time, taking an ASE certification test can be difficult. The questions will not include how things work or other “textbook” knowledge. The questions are based on “real-world” diagnosis and service. The tests may seem tricky to some because the wrong answers are designed to be similar to the correct answer. If this is your first time taking the test or you are going to recertify, start now to prepare. Allocate time each day to study. PRACTICE IS IMPORTANT Many service technicians do not like taking tests. As a result, many technicians rush through the test to get the pain over with quickly. Also, many service technicians have lots of experience on many different vehicles. This is what makes them good at what they do, but when an everyday problem is put into a question format (multiple choice), the answer may not be as clear as your experience has taught you. KEYS TO SUCCESS
The keys to successful test taking include:
Practice answering similar-type questions.
Carefully read each question two times to make sure you understand the question.
Read each answer.
Pick the best answer.
Avoid reading too much into each question.
Do not change an answer unless you are sure that the answer is definitely wrong.
Look over the glossary of automotive terms for words that are not familiar to you.
The best preparation is practice, practice, and more practice. This is where using the ASE Test Prep practice tests can help.
PREPARE MENTALLY
Practicing also helps relieve another potential problem many people have called “chronic test syndrome.” This condition is basically an inability to concentrate or focus during a test. The slightest noise, fear of failure, and worries about other things all contribute. The best medicine is practice, practice, and more practice. With practice, test taking becomes almost second nature.
T E C H N I C I AN C ERT IF IC A T ION
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PREPARE PHYSICALLY
Be prepared physically. Get enough
2. Automatic Transmission/Transaxles (A2) ASE Task List
sleep and eat right. Content Area
ONE MONTH BEFORE THE TEST
Budget your time for studying. On average you will need four to six hours of study for each test that you are taking.
Use the ASE Test Prep Online test preparation service three or more times a week for your practice.
Study with a friend or a group if possible.
THE WEEK BEFORE THE TEST
Studying should consist of about two hours of reviewing for each test being taken.
Make sure you know how to get to the testing center. If possible drive to the test site and locate the room.
Get plenty of rest.
Study time is over.
Keep your work schedule light or get the day off if possible.
Eat a small, light meal the evening of the test.
Drink a large glass of water one to two hours before the test. (The brain and body work on electrical impulses, and water is used as a conductor.)
25
50%
B. In-Vehicle Transmission/Transaxle Repair
12
16%
C. Off-Vehicle Transmission/ Transaxle Repair 1. Removal, Disassembly, and Assembly (3) 2. Gear Train, Shafts, Bushings, Oil Pump, and Case (4) 3. Friction and Reaction Units (4)
13
26%
Total
50
100%
Content Area A. Clutch Diagnosis and Repair
Arrive at least 30 minutes early at the test center. Be ready to start on time.
WHAT TO BRING TO THE TEST
A photo ID.
Your Entry Ticket that came with your ASE packet.
DURING THE TEST
BREATHE (oxygen is the most important nutrient for the brain).
Read every question TWICE.
Read ALL the ANSWERS.
If you have trouble with a question, leave it blank and continue. At the end of the test, go back and try any skipped questions. (Frequently, you will get a hint in another question that follows.)
1. Engine Repair (A1) ASE Task List
7
18%
7
20%
D. Drive (Half) Shaft and Universal Joint/Constant Velocity (CV) Joint Diagnosis and Repair (Front and Rear Wheel Drive)
5
13%
E. Rear Axle Diagnosis and Repair 1. Ring and Pinion Gears (3) 2. Differential Case Assembly (2) 3. Limited Slip Differential (1) 4. Axle Shafts (1)
7
17%
F. Four-Wheel Drive Component Diagnosis and Repair
8
17%
Total
40
100%
Questions Percentage in Test of Test
Content Area
10
25%
11
28%
2
5%
12
30%
5
12%
40
100%
B. Cylinder Head and Valve Train Diagnosis and Repair
10
23%
C. Engine Block Diagnosis and Repair
10
23%
B. Suspension Systems Diagnosis and Repair 1. Front Suspensions (6) 2. Rear Suspensions (5) 3. Miscellaneous Service (2)
14%
C. Related Suspension and Steering Service
12%
D. Wheel Alignment Diagnosis, Adjustment, and Repair
D. Lubrication and Cooling Systems Diagnosis and Repair
8
E. Fuel, Electrical, Ignition, and Exhaust Systems Inspection and Service
7
E. Wheel and Tire Diagnosis and Repair 50
100%
Questions Percentage in Test of Test
A. Steering Systems Diagnosis and Repair 1. Steering Columns and Manual Steering Gears (3) 2. Power-Assisted Steering Units (4) 3. Steering Linkage (3)
28%
CHAPTER 5
15%
B. Transmission Diagnosis and Repair
15
38
6
C. Transaxle Diagnosis and Repair
A. General Engine Diagnosis
Total
Questions Percentage in Test of Test
4. Suspension and Steering (A4) ASE Task List
There are eight automotive certifications including:
Content Area
A. General Transmission/Transaxle Diagnosis 1. Mechanical/Hydraulic Systems (11) 2. Electronic Systems (14)
3. Manual Drive Train and Axles (A3) ASE Task List
THE DAY OF THE TEST
Questions Percentage in Test of Test
Total
7. Heating and Air Conditioning (A7) ASE Task List
5. Brakes (A5) ASE Task List Content Area
Questions Percentage in Test of Test
A. Hydraulic System Diagnosis and Repair 1. Master Cylinders (non-ABS) (3) 2. Fluids, Lines, and Hoses (3) 3. Valves and Switches (non-ABS) (4) 4. Bleeding, Flushing, and Leak Testing (non-ABS) (4)
12
B. Drum Brake Diagnosis and Repair
5
11%
C. Disc Brake Diagnosis and Repair
10
22%
D. Power Assist Units Diagnosis and Repair
4
8%
E. Miscellaneous Diagnosis and Repair
7
16%
F. Antilock Brake System Diagnosis and Repair
7
16%
45
100%
Total
27%
Questions Percentage in Test of Test
Content Area A. A/C System Diagnosis and Repair
13
24%
B. Refrigeration System Component Diagnosis and Repair 1. Compressor and Clutch (5) 2. Evaporator, Condenser, and Related Components (5)
10
20%
4
10%
19
34%
4
12%
50
100%
C. Heating and Engine Cooling Systems Diagnosis and Repair D. Operating Systems and Related Controls Diagnosis and Repair 1. Electrical (9) 2. Vacuum/Mechanical (3) 3. Automatic and Semi-Automatic Heating, Ventilating, and A/C Systems (5) E. Refrigerant Recover, Recycling, and Handling Total
6. Electrical Systems (A6) ASE Task List Content Area
8. Engine Performance (A8) ASE Task List
Questions Percentage in Test of Test
Questions Percentage in Test of Test
Content Area
A. General Electrical/Electronic System Diagnosis
13
26%
A. General Engine Diagnosis
12
17%
B. Battery Diagnosis and Service
4
8%
B. Ignition System Diagnosis and Repair
8
17%
C. Starting System Diagnosis and Repair
5
10%
C. Fuel, Air Induction, and Exhaust Systems Diagnosis and Repair
9
18%
D. Charging System Diagnosis and Repair
5
10%
8
15%
E. Lighting Systems Diagnosis and Repair 1. Headlights, Parking Lights, Taillights, Dash Lights, and Courtesy Lights (3) 2. Stoplights, Turn Signals, Hazard Lights, and Back-up Lights (3)
6
12%
D. Emissions Control Systems Diagnosis and Repair 1. Positive Crankcase Ventilation (1) 2. Exhaust Gas Recirculation (3) 3. Secondary Air Injector (AIR) and Catalytic Converter (2) 4. Evaporative Emissions Controls (3)
13
27%
F. Gauges, Warning Devices, and Driver Information Systems Diagnosis and Repair
6
E. Computerized Engine Controls Diagnosis and Repair (Including OBD II) Total
50
100%
G. Horn and Wiper/Washer Diagnosis and Repair
3
6%
H. Accessories Diagnosis and Repair 1. Body (4) 2. Miscellaneous (4)
8
16%
Total
50
100%
12%
To become certified by ASE, the service technician must have two years of experience and pass a test in each area. If a technician passes all eight automotive certification tests, then the technician is considered a master certified automobile service technician. Tests are administered twice a year, in May and again in November. Registration and payment are required to be sent in early April for the May test and in early October for the November test. Test results are mailed to your home or work address about six to eight weeks after the test(s) is taken.
T E C H N I C I AN C ERT IF IC A T ION
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CANADA’S AUTOMOTIVE APPRENTICESHIP PROGRAM (RED SEAL) In Canada, in all provinces and territories but Quebec and British Columbia, an Inter-Provincial (IP) Certificate is required. An apprenticeship program is in place that takes a minimum of four years, combining ten months in a shop and about two months in school training in each of the four years. Most apprentices must undergo 7200 hours of training before they can complete the IP examination. ASE certifications are currently used on a voluntary basis since 1993, however an IP Certificate is still required. Other licensing of automotive technicians may be required in some cases, such as environmental substances, liquefied petroleum gas, or steam operators.
RE-CERTIFICATION All ASE certifications expire after five years and the technician needs to take a recertification test to remain certified. As vehicles and technology change, it is important that all technicians attend update classes. Most experts recommend that each technician should have at least 40 hours (one full week) of update training every year. Update training classes can be found through many sources, including: 1. Many parts stores and warehouse distributors provide training classes throughout the year. 2. State or regional associations, such as the Automotive Service Association (www.asashop.org), offer update conferences. 3. Local colleges or training companies offer update training. Other training can be found listed on the International Automotive Technicians Network (www.iatn.net).
NOTE: A valid driver’s license is a must for any automotive service technician.
REVIEW QUESTIONS 1. What are the eight ASE test areas? 2. When are the written ASE tests given?
4. What can a technician do to help prepare to take the certification tests?
3. What types of questions are asked on the ASE certification tests?
CHAPTER QUIZ 1. Which ASE certification test would cover experience in reading an electrical schematic? a. A6 b. A7 c. A8 d. All of the above are possible 2. How many ASE tests must be passed to become a master automotive technician? a. 8 b. 6 c. 4 d. 2 3. How many years of experience are required to achieve ASE certification? a. 8 c. 4 b. 6 d. 2 4. Credit for how many years of work experience can be substituted by attending automotive service training? a. None—no substitution for work experience is permitted b. 1 year c. 2 years d. 3 years 5. When taking an ASE certification test, ________. a. You can write on the test itself if you wish b. No marks are allowed on the test c. Only one test can be taken d. Some hands-on activities may be required
40
CHAPTER 5
6. A type of test question not asked on the ASE certification test is ________. a. Most likely c. Fill in the blank b. Least likely d. Multiple choice 7. Which type of question is the same as two true-and-false-type questions? a. All except type b. Technician A and Technician B c. Least likely type d. Most likely type 8. Technician A says that you should guess if you do not know the correct answer. Technician B says that ASE will send you the correct answers to the questions you missed with your test results. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 9. The written ASE tests are given every ________. a. January and June c. February and September b. May and November d. March and October 10. A technician should do all of the following to prepare to take the ASE certification test except ________. a. Get a good night’s sleep the night before the test b. Try to keep work schedule light the day of the test c. Eat a big meal d. Have photo ID and entry ticket
S E C T I O N
6
II
Safety, Environmental, and Health Concerns 7
Shop Safety
chapter
Environmental and Hazardous Materials
SHOP SAFETY
6 OBJECTIVES: After studying Chapter 6, the reader should be able to: • Identify situations where hearing protection should be worn. • Discuss how to safely handle tools and shop equipment. • Describe how to properly use a fire extinguisher. • Discuss shop safety procedures. KEY TERMS: ANSI 41 • Bump cap 42 • Decibel (dB) 42 • Eye wash station 46 • Fire blankets 46 • Microbes 44 • “PASS” 45 • Personal protective equipment (PPE) 41 • Spontaneous combustion 43
PERSONAL PROTECTIVE EQUIPMENT Safety is not just a buzzword on a poster in the work area. Safe work habits can reduce accidents and injuries, ease the workload, and keep employees pain free.
SAFETY GLASSES The most important personal protective equipment (PPE) a technician should wear all the time are safety glasses, which meet standard ANSI Z87.1. SEE FIGURE 6–1. STEEL-TOED SHOES
Steel-toed safety shoes are also a good investment. SEE FIGURE 6–2. If safety shoes are not available, then leather-topped shoes offer more protection than canvas or cloth covered shoes.
GLOVES
Wear gloves to protect your hands from rough or sharp surfaces. Thin rubber gloves are recommended when working around automotive liquids such as engine oil, antifreeze, transmission fluid, or any other liquids that may be hazardous. Several types of gloves and their characteristics include:
FIGURE 6–1 Safety glasses should be worn at all times when working on or around any vehicle or servicing any component.
Latex surgical gloves. These gloves are relatively inexpensive, but tend to stretch, swell, and weaken when exposed to gas, oil, or solvents.
Vinyl gloves. These gloves are also inexpensive and are not affected by gas, oil, or solvents. SEE FIGURE 6–3.
Polyurethane gloves. These gloves are more expensive, yet very strong. Even though these gloves are also not affected by gas, oil, or solvents, they tend to be slippery.
Nitrile gloves. These gloves are exactly like latex gloves, but are not affected by gas, oil, or solvents, yet they tend to be expensive.
S H OP S A F ET Y
41
FIGURE 6–2 Steel-toed shoes are a worthwhile investment to help prevent foot injury due to falling objects. Even these well-worn shoes can protect the feet of this service technician.
FIGURE 6–4 One version of a bump cap is this padded plastic insert that is worn inside a regular cloth cap.
FIGURE 6–5 Remove all jewelry before performing service work on any vehicle. FIGURE 6–3 Protective gloves such as these vinyl gloves are available in several sizes. Select the size that allows the gloves to fit snugly. Vinyl gloves last a long time and often can be worn all day to help protect your hands from dirt and possible hazardous materials.
TECH TIP Professional Behavior in the Shop Is a Must To be respected as a professional service technician and for safety, always behave in a professional manner. These behaviors include, but are not limited to the following:
Mechanic’s gloves. These gloves are usually made of synthetic leather and spandex and provide thermo protection, as well as protection from dirt and grime.
• Show respect to other technicians and employees. For example, the shop owner or service manager may not always be right, but they are always the boss. • Avoid horseplay or practical jokes. • Act as if a customer is observing your behavior at all times because this is often the case.
BUMP CAP
Service technicians working under a vehicle should wear a bump cap to protect the head against under-vehicle objects and the pads of the lift. SEE FIGURE 6–4.
HANDS, JEWELRY, AND CLOTHING
Remove jewelry that may get caught on something or act as a conductor to an exposed electrical circuit. SEE FIGURE 6–5. Take care of your hands. Keep your hands clean by washing with soap and hot water that is at least 110°F (43°C). Avoid loose or dangling clothing. Also, ear protection should be worn if the sound around you requires that you raise your voice (sound level higher than 90 decibels [dB]). NOTE: A typical lawnmower produces noise at a level of about 110 dB. This means that everyone who uses a lawnmower or other lawn or garden equipment should wear ear protection.
42
CHAPTER 6
SAFETY TIPS FOR TECHNICIANS
When lifting any object, get a secure grip with solid footing. Keep the load close to your body to minimize the strain. Lift with your legs and arms, not your back.
FIGURE 6–8 An electric pusher used to push vehicles into or around the shop. FIGURE 6–6 Always connect an exhaust hose to the tailpipe of the engine of a vehicle to be run inside a building.
FIGURE 6–9 All oily shop cloths should be stored in a metal container equipped with a lid to help prevent spontaneous combustion. FIGURE 6–7 A magnetic tray is a helpful item to keep tools needed up where they can be easily reached without having to bend over saving time and energy over the course of a long day in the shop.
SAFETY TIP Shop Cloth Disposal Always dispose of oily shop cloths in an enclosed container to prevent a fire. SEE FIGURE 6–9. Whenever oily cloths are thrown together on the floor or workbench, a chemical reaction can occur which can ignite the cloth even without an open flame. This process of ignition without an open flame is called spontaneous combustion.
Do not twist your body when carrying a load. Instead, pivot your feet to help prevent strain on the spine.
Ask for help when moving or lifting heavy objects.
Push a heavy object rather than pull it. (This is opposite to the way you should work with tools—never push a wrench! If you do and a bolt or nut loosens, your entire weight is used to propel your hand(s) forward. This usually results in cuts, bruises, or other painful injury.)
Always connect an exhaust hose to the tailpipe of any running vehicle to help prevent the buildup of carbon dioxide (CO) inside a closed garage space. SEE FIGURE 6–6.
When standing, keep objects, parts, and tools with which you are working between chest height and waist height. If seated, work at tasks that are at elbow height. SEE FIGURE 6–7.
There are four basic types of cleaning methods and processes used in vehicle service.
Always be sure the hood is securely held open.
Ask for help when pushing a vehicle or use a motorized pusher. SEE FIGURE 6–8.
POWER WASHING Power washing uses an electric- or gasoline-powered compressor to increase the pressure of water and force it out of a nozzle. The pressure of the water itself is usually
CLEANING METHODS AND PROCESSES
S H OP S A F ET Y
43
TO STARTER MOTOR
TO STARTER MOTOR
STEP 2
STEP 1
STALLED VEHICLE
STARTING VEHICLE
TO ENGINE GROUND
TO ENGINE GROUND
STEP 3 STEP 4
ENGINE BLOCK OR METAL BRACKET ON ENGINE BLOCK
FIGURE 6–10 Jumper cable usage guide.
ABRASIVE CLEANING
TECH TIP Pound with Something Softer If you must pound on something, be sure to use a tool that is softer than what you are about to pound on to avoid damage. Examples are given in the following table. The Material Being Pounded
What to Pound With
Steel or cast iron
Brass or aluminum hammer or punch
Aluminum
Plastic or rawhide mallet or plastic-covered dead-blow hammer
Plastic
Rawhide mallet or plastic dead-blow hammer
enough to remove dirt, grease, and grime from vehicle components. Sometimes a chemical cleaner, such as a detergent, is added to the water to help with cleaning. SAFE USE OF POWER WASHERS. Because water is being sprayed at high pressure, a face shield should be worn when using a power washer to protect not only the eyes but also the face in the event of the spray being splashed back toward the technician. Also use a pressure washer in an area where the runoff from the cleaning will not contaminate local groundwater or cause harm to plants or animals.
Abrasive cleaning is used to clean disassembled parts, such as engine blocks. The abrasives used include steel shot, ground walnut shells, or in the case of cleaning paint from a vehicle body, baking soda can be used. SAFE USE OF ABRASIVE CLEANERS. Always wear a protective face shield and protective clothing, including gloves, long sleeves, and long pants.
THERMAL OVENS
Thermal cleaning uses heat to bake off grease and dirt with special high-temperature ovens. This method of cleaning requires the use of expensive equipment but does not use any hazardous chemicals and is environmentally safe. SAFE USE OF THERMAL OVENS. Because thermal ovens operate at high temperatures, often exceeding 600°F (315°C), the oven should be turned off and allowed to cool overnight before removing the parts from the oven to avoid being exposed to the high temperature.
ELECTRICAL CORD SAFETY Use correctly grounded three-prong sockets and extension cords to operate power tools. Some tools use only two-prong plugs. Make sure these are double insulated and repair or replace any electrical cords that are cut or damaged to prevent the possibility of an electrical shock. When not in use, keep electrical cords off the floor to prevent tripping over them. Tape the cords down if they are placed in high foot traffic areas.
CHEMICAL/MICROBE CLEANING
Chemical cleaning involves one of several cleaning solutions, including detergent, solvents, or small, living microorganisms called microbes that eat oil and grease. The microbes live in water and eat the hydrocarbons that are the basis of grease and oil. SAFE USE OF CHEMICAL CLEANING. A face shield should be worn when cleaning parts using a chemical cleaner. Avoid spilling the cleaner on the floor to help prevent slipping accidents. Clean and replace the chemical cleaner regularly.
44
CHAPTER 6
JUMP-STARTING AND BATTERY SAFETY To jump-start another vehicle with a dead battery, connect goodquality copper jumper cables as indicated in FIGURE 6–10 or use a jump box. The last connection made should always be on the
FIGURE 6–11 The air pressure going to the nozzle should be reduced to 30 PSI or less.
FIGURE 6–12 A typical fire extinguisher designed to be used on type class A, B, or C fires.
SAFETY TIP Compressed Air Safety Improper use of an air nozzle can cause blindness or deafness. Compressed air must be reduced to less than 30 PSI (206 kPa). SEE FIGURE 6–11. If an air nozzle is used to dry and clean parts, make sure the air stream is directed away from anyone else in the immediate area. Always use an OSHA-approved nozzle with side slits that limit the maximum pressure at the nozzle to 30 PSI. Coil and store air hoses when they are not in use.
engine block or an engine bracket as far from the battery as possible. It is normal for a spark to be created when the jumper cables finally complete the jumper cable connections, and this spark could cause an explosion of the gases around the battery. Many newer vehicles have special ground connections built away from the battery just for the purpose of jump-starting. Check the owner manual or service information for the exact location. Batteries contain acid and should be handled with care to avoid tipping them greater than a 45-degree angle. Always remove jewelry when working around a battery to avoid the possibility of electrical shock or burns, which can occur when the metal comes in contact with a 12 volt circuit and ground, such as the body of the vehicle.
FIGURE 6–13 A CO2 fire extinguisher being used on a fire set in an open steel drum during a demonstration at a fire department training center.
Class D is effective only on combustible metals such as powdered aluminum, sodium, or magnesium.
The class rating is clearly marked on the side of every fire extinguisher. Many extinguishers are good for multiple types of fires. SEE FIGURE 6–12. When using a fire extinguisher, remember the word “PASS.” P Pull the safety pin.
FIRE EXTINGUISHERS CLASSES OF FIRE EXTINGUISHERS
There are four classes of fire extinguishers. Each class should be used on specific fires only.
Class A is designed for use on general combustibles, such as cloth, paper, and wood. Class B is designed for use on flammable liquids and greases, including gasoline, oil, thinners, and solvents. Class C is used only on electrical fires.
A Aim the nozzle of the extinguisher at the base of the fire. S Squeeze the lever to actuate the extinguisher. S Sweep the nozzle from side to side.
SEE FIGURE 6–13.
TYPES OF FIRE EXTINGUISHERS
Types of fire extinguish-
ers include the following:
Water. A water fire extinguisher, usually in a pressurized container, is good to use on Class A fires by reducing the temperature to the point where a fire cannot be sustained.
S H OP S A F ET Y
45
FIGURE 6–14 A treated wool blanket is kept in this easy-to-open wall-mounted holder and should be placed in a centralized location in the shop.
Carbon dioxide (CO2). A carbon dioxide fire extinguisher is good for almost any type of fire, especially Class B or Class C materials. A CO2 fire extinguisher works by removing the oxygen from the fire and the cold CO2 also helps reduce the temperature of the fire.
Dry chemical (yellow). A dry chemical fire extinguisher is good for Class A, B, or C fires by coating the flammable materials, which eliminates the oxygen from the fire. A dry chemical fire extinguisher tends to be very corrosive and will cause damage to electronic devices.
FIGURE 6–15 A first aid box should be centrally located in the shop and kept stocked with the recommended supplies.
FIRE BLANKETS Fire blankets are required to be available in the shop areas. If a person is on fire, a fire blanket should be removed from its storage bag and thrown over and around the victim to smother the fire. SEE FIGURE 6–14 showing a typical fire blanket.
FIRST AID AND EYE WASH STATIONS All shop areas must be equipped with a first aid kit and an eye wash station centrally located and kept stocked with emergency supplies.
FIRST AID KIT
A first aid kit should include:
Bandages (variety)
Gauze pads
Roll gauze
Iodine swab sticks
Antibiotic ointment
Hydrocortisone cream
Burn gel packets
Eye wash solution
46
CHAPTER 6
FIGURE 6–16 A typical eye wash station. Often a thorough flushing of the eyes with water is the best treatment in the event of eye contamination.
Scissors
Tweezers
Gloves
First aid guide
SEE FIGURE 6–15. Every shop should have a person trained in first aid. If there is an accident, call for help immediately.
EYE WASH STATION
An eye wash station should be centrally located and used whenever any liquid or chemical gets into the eyes. If such an emergency does occur, keep eyes in a constant stream of water and call for professional assistance. SEE FIGURE 6–16.
TECH TIP Mark Off the Service Area Some shops rope off the service bay area to help keep traffic and distractions to a minimum, which could prevent personal injury. SEE FIGURE 6–17.
FIGURE 6–17 This area has been blocked off to help keep visitors from the dangerous work area.
REVIEW QUESTIONS 1. List four items that are personal protective equipment (PPE).
3. What items are included in a typical first aid box?
2. What are the types of fire extinguishers and their usage?
CHAPTER QUIZ 1. What do you call the service technician’s protective head cover? a. Cap c. Bump cap b. Hat d. Helmet 2. All safety glasses should meet the standards set by ______________. a. ANSI c. ASE b. SAE d. DOT 3. When washing hands, the water should be at what temperature? a. 98°F (37°C) c. 125°F (52°C) b. 110°F (43°C) d. 135°F (57°C) 4. Hearing protection should be worn anytime the noise level exceeds ______________. a. 60 dB c. 80 dB b. 70 dB d. 90 dB 5. Two technicians are discussing the safe use of a wrench. Technician A says that a wrench should be pulled toward you. Technician B says that a wrench should be pushed away from you. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
6. Exhaust hoses should be used because one of the exhaust gases is deadly in high concentration. This gas is ______________. a. Carbon monoxide (CO) b. Carbon dioxide (CO2) c. Hydrocarbons (HC) d. Oxides of nitrogen (NOX) 7. The process of combustion occurring without an open flame is called ______________. a. Direct ignition b. Non-open flame combustion c. Spontaneous combustions d. Cold fusion 8. When using a fire extinguisher, what word can be used to remember what to do? a. PASS c. RED b. FIRE d. LEVER 9. Which type of fire extinguisher can create a corrosive compound when discharged? a. CO2 c. Water b. Dry chemical d. CO 10. Which item is usually not included in a first aid kit? a. Eye wash solution c. Fire blanket b. Antibiotic cream d. Bandages
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chapter
7
ENVIRONMENTAL AND HAZARDOUS MATERIALS
OBJECTIVES: After studying Chapter 7, the reader should be able to: • Prepare for the ASE assumed knowledge content required by all service technicians to adhere to environmentally appropriate actions and behavior. • Define the Occupational Safety and Health Act (OSHA). • Explain the term material safety data sheet (MSDS). • Identify hazardous waste materials in accordance with state and federal regulations and follow proper safety precautions while handling hazardous waste materials. • Define the steps required to safely handle and store automotive chemicals and waste. KEY TERMS: Aboveground storage tank (AGST) 51 • Asbestosis 49 • BCI 53 • CAA 49 • CFR 48 • EPA 48 • Hazardous waste material 48 • HEPA vacuum 50 • Mercury 54 • MSDS 49 • OSHA 48 • RCRA 49 • Right-to-know laws 49 • Solvent 50 • Underground storage tank (UST) 51 • Used oil 50 • WHMIS 49
HAZARDOUS WASTE DEFINITION OF HAZARDOUS WASTE
Hazardous waste materials are chemicals, or components, that the shop no longer needs that pose a danger to the environment and people if they are disposed of in ordinary garbage cans or sewers. However, no material is considered hazardous waste until the shop has finished using it and is ready to dispose of it.
monitor, control, and educate workers regarding health and safety in the workplace.
EPA The Environmental Protection Agency (EPA) publishes a list of hazardous materials that is included in the Code of Federal Regulations (CFR). The EPA considers waste hazardous if it is included on the EPA list of hazardous materials, or it has one or more of the following characteristics:
Reactive. Any material that reacts violently with water or other chemicals is considered hazardous.
Corrosive. If a material burns the skin, or dissolves metals and other materials, a technician should consider it hazardous. A pH scale is used, with the number 7 indicating neutral. Pure water has a pH of 7. Lower numbers indicate an acidic solution and higher numbers indicate a caustic solution. If a material releases cyanide gas, hydrogen sulfide gas, or similar gases when exposed to low pH acid solutions, it is considered hazardous.
Toxic. Materials are hazardous if they leak one or more of eight different heavy metals in concentrations greater than 100 times the primary drinking water standard.
Ignitable. A liquid is hazardous if it has a flash point below 140°F (60°C), and a solid is hazardous if it ignites spontaneously.
Radioactive. Any substance that emits measurable levels of radiation is radioactive. When individuals bring containers of a highly radioactive substance into the shop environment, qualified personnel with the appropriate equipment must test them.
PERSONAL PROTECTIVE EQUIPMENT (PPE)
When handling hazardous waste material, one must always wear the proper protective clothing and equipment detailed in the right-to-know laws. This includes respirator equipment. All recommended procedures must be followed accurately. Personal injury may result from improper clothing, equipment, and procedures when handling hazardous materials.
FEDERAL AND STATE LAWS OCCUPATIONAL SAFETY AND HEALTH ACT
The United States Congress passed the Occupational Safety and Health Act (OSHA) in 1970. This legislation was designed to assist and encourage the citizens of the United States in their efforts to assure:
Safe and healthful working conditions by providing research, information, education, and training in the field of occupational safety and health.
Safe and healthful working conditions for working men and women by authorizing enforcement of the standards developed under the Act.
Because about 25% of workers are exposed to health and safety hazards on the job, the OSHA standards are necessary to
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WARNING Hazardous waste disposal laws include serious penalties for anyone responsible for breaking these laws.
hazardous material users are responsible for hazardous materials from the time they become a waste until the proper waste disposal is completed. Many shops hire an independent hazardous waste hauler to dispose of hazardous waste material. The shop owner, or manager, should have a written contract with the hazardous waste hauler. Rather than have hazardous waste material hauled to an approved hazardous waste disposal site, a shop may choose to recycle the material in the shop. Therefore, the user must store hazardous waste material properly and safely, and be responsible for the transportation of this material until it arrives at an approved hazardous waste disposal site, where it can be processed according to the law. The RCRA controls the following types of automotive waste:
FIGURE 7–1 Material safety data sheets (MSDS) should be readily available for use by anyone in the area who may come into contact with hazardous materials.
RIGHT-TO-KNOW LAWS
The right-to-know laws state that employees have a right to know when the materials they use at work are hazardous. The right-to-know laws started with the Hazard Communication Standard published by OSHA in 1983. Originally, this document was intended for chemical companies and manufacturers that required employees to handle hazardous materials in their work situation but the federal courts have decided to apply these laws to all companies, including automotive service shops. Under the right-toknow laws, the employer has responsibilities regarding the handling of hazardous materials by their employees. All employees must be trained about the types of hazardous materials they will encounter in the workplace. The employees must be informed about their rights under legislation regarding the handling of hazardous materials. MATERIAL SAFETY DATA SHEETS (MSDS). All hazardous materials must be properly labeled, and information about each hazardous material must be posted on material safety data sheets (MSDS) available from the manufacturer. In Canada, MSDS information is called Workplace Hazardous Materials Information Systems (WHMIS). The employer has a responsibility to place MSDS information where they are easily accessible by all employees. The MSDS information provide the following information about the hazardous material: chemical name, physical characteristics, protective handling equipment, explosion/fire hazards, incompatible materials, health hazards, medical conditions aggravated by exposure, emergency and first aid procedures, safe handling, and spill/leak procedures. The employer also has a responsibility to make sure that all hazardous materials are properly labeled. The label information must include health, fire, and reactivity hazards posed by the material, as well as the protective equipment necessary to handle the material. The manufacturer must supply all warning and precautionary information about hazardous materials. This information must be read and understood by the employee before handling the material. SEE FIGURE 7–1.
RESOURCE CONSERVATION AND RECOVERY ACT (RCRA) Federal and state laws control the disposal of hazardous waste materials and every shop employee must be familiar with these laws. Hazardous waste disposal laws include the Resource Conservation and Recovery Act (RCRA). This law states that
Paint and body repair products waste
Solvents for parts and equipment cleaning
Batteries and battery acid
Mild acids used for metal cleaning and preparation
Waste oil, and engine coolants or antifreeze
Air-conditioning refrigerants and oils
Engine oil filters
CLEAN AIR ACT
Air-conditioning (A/C) systems and refrigerant are regulated by the Clean Air Act (CAA), Title VI, Section 609. Technician certification and service equipment is also regulated. Any technician working on automotive A/C systems must be certified. A/C refrigerants must not be released or vented into the atmosphere, and used refrigerants must be recovered.
ASBESTOS HAZARDS Friction materials such as brake and clutch linings often contain asbestos. While asbestos has been eliminated from most original equipment friction materials, the automotive service technician cannot know whether the vehicle being serviced is or is not equipped with friction materials containing asbestos. It is important that all friction materials be handled as if they do contain asbestos. Asbestos exposure can cause scar tissue to form in the lungs. This condition is called asbestosis. It gradually causes increasing shortness of breath, and the scarring to the lungs is permanent. Even low exposures to asbestos can cause mesothelioma, a type of fatal cancer of the lining of the chest or abdominal cavity. Asbestos exposure can also increase the risk of lung cancer as well as cancer of the voice box, stomach, and large intestine. It usually takes 15 to 30 years or more for cancer or asbestos lung scarring to show up after exposure. Scientists call this the latency period. Government agencies recommend that asbestos exposure be eliminated or controlled to the lowest level possible. These agencies have developed recommendations and standards that the automotive service technician and equipment manufacturer should follow. These U.S. federal agencies include the National Institute for Occupational Safety and Health (NIOSH), Occupational Safety and Health Administration (OSHA), and Environmental Protection Agency (EPA).
ASBESTOS OSHA STANDARDS The Occupational Safety and Health Administration (OSHA) has established three levels of asbestos exposure. Any vehicle service establishment that does either
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brake or clutch work must limit employee exposure to asbestos to less than 0.2 fibers per cubic centimeter (cc) as determined by an air sample. If the level of exposure to employees is greater than specified, corrective measures must be performed and a large fine may be imposed. NOTE: Research has found that worn asbestos fibers such as those from automotive brakes or clutches may not be as hazardous as first believed. Worn asbestos fibers do not have sharp flared ends that can latch onto tissue, but rather are worn down to a dust form that resembles talc. Grinding or sawing operations on unworn brake shoes or clutch discs will contain harmful asbestos fibers. To limit health damage, always use proper handling procedures while working around any component that may contain asbestos.
ASBESTOS EPA REGULATIONS
The federal Environmental Protection Agency (EPA) has established procedures for the removal and disposal of asbestos. The EPA procedures require that products containing asbestos be “wetted” to prevent the asbestos fibers from becoming airborne. According to the EPA, asbestos-containing materials can be disposed of as regular waste. Only when asbestos becomes airborne is it considered to be hazardous.
ASBESTOS HANDLING GUIDELINES
The air in the shop area can be tested by a testing laboratory, but this can be expensive. Tests have determined that asbestos levels can easily be kept below the recommended levels by using a liquid, like water, or a special vacuum. NOTE: The service technician cannot tell whether the old brake pads, shoes, or clutch discs contain asbestos. Therefore, to be safe, the technician should assume that all brake pads, shoes, or clutch discs contain asbestos.
HEPA VACUUM. A special high-efficiency particulate air (HEPA) vacuum system has been proven to be effective in keeping asbestos exposure levels below 0.1 fibers per cubic centimeter. SOLVENT SPRAY. Many technicians use an aerosol can of brake cleaning solvent to wet the brake dust and prevent it from becoming airborne. A solvent is a liquid that is used to dissolve dirt, grime, or solid particles. Commercial brake cleaners are available that use a concentrated cleaner that is mixed with water. SEE FIGURE 7–2. The waste liquid is filtered, and when dry, the filter can be disposed of as solid waste. DISPOSAL OF BRAKE DUST AND BRAKE SHOE. The hazard of asbestos occurs when asbestos fibers are airborne. Once the asbestos has been wetted down, it is then considered to be solid waste, rather than hazardous waste. Old brake shoes and pads should be enclosed, preferably in a plastic bag, to help prevent any of the brake material from becoming airborne. Always follow current federal and local laws concerning disposal of all waste.
WARNING Never use compressed air to blow brake dust. The fine talclike brake dust can create a health hazard even if asbestos is not present or is present in dust rather than fiber form.
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FIGURE 7–2 All brakes should be moistened with water or solvent to help prevent brake dust from becoming airborne.
USED BRAKE FLUID Most brake fluid is made from polyglycol, is water soluble, and can be considered hazardous if it has absorbed metals from the brake system.
STORAGE AND DISPOSAL OF BRAKE FLUID
Collect brake fluid in a container clearly marked to indicate that it is designated for that purpose.
If the waste brake fluid is hazardous, be sure to manage it appropriately and use only an authorized waste receiver for its disposal.
If the waste brake fluid is nonhazardous (such as old, but unused), determine from your local solid waste collection provider what should be done for its proper disposal.
Do not mix brake fluid with used engine oil.
Do not pour brake fluid down drains or onto the ground.
Recycle brake fluid through a registered recycler.
USED OIL Used oil is any petroleum-based or synthetic oil that has been used. During normal use, impurities such as dirt, metal scrapings, water, or chemicals can get mixed in with the oil. Eventually, this used oil must be replaced with virgin or re-refined oil. The EPA’s used oil management standards include a three-pronged approach to determine if a substance meets the definition of used oil. To meet the EPA’s definition of used oil, a substance must meet each of the following three criteria.
Origin. The first criterion for identifying used oil is based on the oil’s origin. Used oil must have been refined from crude oil or made from synthetic materials. Animal and vegetable oils are excluded from the EPA’s definition of used oil.
Use. The second criterion is based on whether and how the oil is used. Oils used as lubricants, hydraulic fluids, heat transfer fluids, and for other similar purposes are considered
NEVER STORE USED OIL IN ANYTHING OTHER THAN TANKS AND STORAGE CONTAINERS. Used oil may also be stored in units that are permitted to store regulated hazardous waste. USED OIL FILTER DISPOSAL REGULATIONS. Used oil filters contain used engine oil that may be hazardous. Before an oil filter is placed into the trash or sent to be recycled, it must be drained using one of the following hot-draining methods approved by the EPA.
FIGURE 7–3 A typical aboveground oil storage tank.
used oil. The EPA’s definition also excludes products used as cleaning agents, as well as certain petroleum-derived products like antifreeze and kerosene.
Contaminants. The third criterion is based on whether the oil is contaminated with either physical or chemical impurities. In other words, to meet the EPA’s definition, used oil must become contaminated as a result of being used. This aspect of the EPA’s definition includes residues and contaminants generated from handling, storing, and processing used oil.
NOTE: The release of only 1 gallon of used oil (a typical oil change) can make 1 million gallons of fresh water undrinkable. If used oil is dumped down the drain and enters a sewage treatment plant, concentrations as small as 50 to 100 parts per million (ppm) in the wastewater can foul sewage treatment processes. Never mix a listed hazardous waste, gasoline, wastewater, halogenated solvent, antifreeze, or an unknown waste material with used oil. Adding any of these substances will cause the used oil to become contaminated, which classifies it as hazardous waste.
STORAGE AND DISPOSAL OF USED OIL Once oil has been used, it can be collected, recycled, and used over and over again. An estimated 380 million gallons of used oil are recycled each year. Recycled used oil can sometimes be used again for the same job or can take on a completely different task. For example, used engine oil can be re-refined and sold at some discount stores as engine oil or processed for furnace fuel oil. After collecting used oil in an appropriate container such as a 55 gallon steel drum, the material must be disposed of in one of two ways.
Shipped offsite for recycling
Burned in an onsite or offsite EPA-approved heater for energy recovery
Used oil must be stored in compliance with an existing underground storage tank (UST) or an aboveground storage tank (AGST) standard, or kept in separate containers. SEE FIGURE 7–3. Containers are portable receptacles, such as a 55 gallon steel drum. KEEP USED OIL STORAGE DRUMS IN GOOD CONDITION. This means that they should be covered, secured from vandals, properly labeled, and maintained in compliance with local fire codes. Frequent inspections for leaks, corrosion, and spillage are an essential part of container maintenance.
Puncture the filter antidrainback valve or filter dome end and hot drain for at least 12 hours
Hot draining and crushing
Dismantling and hot draining
Any other hot-draining method, which will remove all the used oil from the filter
After the oil has been drained from the oil filter, the filter housing can be disposed of in any of the following ways.
Sent for recycling
Picked up by a service contract company
Disposed of in regular trash
SOLVENTS The major sources of chemical danger are liquid and aerosol brake cleaning fluids that contain chlorinated hydrocarbon solvents. Several other chemicals that do not deplete the ozone, such as heptane, hexane, and xylene, are now being used in nonchlorinated brake cleaning solvents. Some manufacturers are also producing solvents they describe as environmentally responsible, which are biodegradable and noncarcinogenic (not cancer causing). There is no specific standard for physical contact with chlorinated hydrocarbon solvents or the chemicals replacing them. All contact should be avoided whenever possible. The law requires an employer to provide appropriate protective equipment and ensure proper work practices by an employee handling these chemicals.
EFFECTS OF CHEMICAL POISONING The effects of exposure to chlorinated hydrocarbon and other types of solvents can take many forms. Short-term exposure at low levels can cause symptoms such as:
Headache
Nausea
Drowsiness
Dizziness
Lack of coordination
Unconsciousness
It may also cause irritation of the eyes, nose, and throat, and flushing of the face and neck. Short-term exposure to higher concentrations can cause liver damage with symptoms such as yellow jaundice or dark urine. Liver damage may not become evident until several weeks after the exposure.
HAZARDOUS SOLVENTS AND REGULATORY STATUS Most solvents are classified as hazardous wastes. Other characteristics of solvents include the following:
Solvents with flash points below 140°F (60°C) are considered flammable and, like gasoline, are federally regulated by the Department of Transportation (DOT).
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FIGURE 7–4 Washing hands and removing jewelry are two important safety habits all service technicians should practice. FIGURE 7–5 Typical fireproof flammable storage cabinet. SAFETY TIP Hand Safety Service technicians should wash their hands with soap and water after handling engine oil, differential oil, or transmission fluids or wear protective rubber gloves. Another safety hint is that the service technician should not wear watches, rings, or other jewelry that could come in contact with electrical or moving parts of a vehicle. SEE FIGURE 7–4.
Solvents and oils with flash points above 60°C are considered combustible and, like engine oil, are also regulated by the DOT. All flammable items must be stored in a fireproof container. SEE FIGURE 7–5.
It is the responsibility of the repair shop to determine if its spent solvent is hazardous waste. Solvent reclaimers are available that clean and restore the solvent so it lasts indefinitely.
USED SOLVENTS Used or spent solvents are liquid materials that have been generated as waste and may contain xylene, methanol, ethyl ether, and methyl isobutyl ketone (MIBK). These materials must be stored in OSHA-approved safety containers with the lids or caps closed tightly. Additional requirements include the following:
Containers should be clearly labeled “Hazardous Waste” and the date the material was first placed into the storage receptacle should be noted.
Labeling is not required for solvents being used in a parts washer.
Used solvents will not be counted toward a facility’s monthly output of hazardous waste if the vendor under contract removes the material.
52
Used solvents may be disposed of by recycling with a local vendor, such as SafetyKleen®, to have the used solvent removed according to specific terms in the vendor agreement. Use aqueous-based (nonsolvent) cleaning systems to help avoid the problems associated with chemical solvents. SEE FIGURE 7–6.
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FIGURE 7–6 Using a water-based cleaning system helps reduce the hazards from using strong chemicals.
?
FREQUENTLY ASKED QUESTION
How Can You Tell If a Solvent Is Hazardous? If a solvent or any of the ingredients of a product contains “fluor” or “chlor” then it is likely to be hazardous. Check the instructions on the label for proper use and disposal procedures.
COOLANT DISPOSAL Coolant is a mixture of antifreeze and water. New antifreeze is not considered to be hazardous even though it can cause death if ingested. Used antifreeze may be hazardous due to dissolved metals from the engine and other components of the cooling system. These metals can include iron, steel, aluminum, copper, brass, and lead
FIGURE 7–7 Used antifreeze coolant should be kept separate and stored in a leakproof container until it can be recycled or disposed of according to federal, state, and local laws. Note that the storage barrel is placed inside another container to catch any coolant that may spill out of the inside barrel. (from older radiators and heater cores). Coolant should be disposed of in one of the following ways:
Coolant should be recycled either onsite or offsite.
Used coolant should be stored in a sealed and labeled container. SEE FIGURE 7–7.
Used coolant can often be disposed of into municipal sewers with a permit. Check with local authorities and obtain a permit before discharging used coolant into sanitary sewers.
FIGURE 7–8 This red gasoline container holds about 30 gallons of gasoline and is used to fill vehicles used for training.
plates contain lead, which is highly poisonous. For this reason, disposing of batteries improperly can cause environmental contamination and lead to severe health problems.
BATTERY HANDLING AND STORAGE
LEAD-ACID BATTERY WASTE About 70 million spent lead-acid batteries are generated each year in the United States alone. Lead is classified as a toxic metal and the acid used in lead-acid batteries is highly corrosive. The vast majority (95% to 98%) of these batteries are recycled through lead reclamation operations and secondary lead smelters for use in the manufacture of new batteries.
BATTERY DISPOSAL
Used lead-acid batteries must be reclaimed or recycled in order to be exempt from hazardous waste regulations. Leaking batteries must be stored and transported as hazardous waste. Some states have more strict regulations, which require special handling procedures and transportation. According to the Battery Council International (BCI), battery laws usually include the following rules. 1. Lead-acid battery disposal is prohibited in landfills or incinerators. Batteries are required to be delivered to a battery retailer, wholesaler, recycling center, or lead smelter. 2. All retailers of automotive batteries are required to post a sign that displays the universal recycling symbol and indicates the retailer’s specific requirements for accepting used batteries. 3. Battery electrolyte contains sulfuric acid, which is a very corrosive substance capable of causing serious personal injury, such as skin burns and eye damage. In addition, the battery
Batteries, whether new or used, should be kept indoors if possible. The storage location should be an area specifically designated for battery storage and must be well ventilated (to the outside). If outdoor storage is the only alternative, a sheltered and secured area with acid-resistant secondary containment is strongly recommended. It is also advisable that acid-resistant secondary containment be used for indoor storage. In addition, batteries should be placed on acid-resistant pallets and never stacked.
FUEL SAFETY AND STORAGE Gasoline is a very explosive liquid. The expanding vapors that come from gasoline are extremely dangerous. These vapors are present even in cold temperatures. Vapors formed in gasoline tanks on many vehicles are controlled, but vapors from gasoline storage may escape from the can, resulting in a hazardous situation. Therefore, place gasoline storage containers in a well-ventilated space. Although diesel fuel is not as volatile as gasoline, the same basic rules apply to diesel fuel and gasoline storage. These rules include the following: 1. Use storage cans that have a flash-arresting screen at the outlet. These screens prevent external ignition sources from igniting the gasoline within the can when someone pours the gasoline or diesel fuel. 2. Use only a red approved gasoline container to allow for proper hazardous substance identification. SEE FIGURE 7–8.
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3. Do not fill gasoline containers completely full. Always leave the level of gasoline at least 1 in. from the top of the container. This action allows expansion of the gasoline at higher temperatures. If gasoline containers are completely full, the gasoline will expand when the temperature increases. This expansion forces gasoline from the can and creates a dangerous spill. If gasoline or diesel fuel containers must be stored, place them in a designated storage locker or facility. 4. Never leave gasoline containers open, except while filling or pouring gasoline from the container. 5. Never use gasoline as a cleaning agent. 6. Always connect a ground strap to containers when filling or transferring fuel or other flammable products from one container to another to prevent static electricity that could result in explosion and fire. These ground wires prevent the buildup of a static electric charge, which could result in a spark and disastrous explosion.
AIRBAG HANDLING Airbag modules are pyrotechnic devices that can be ignited if exposed to an electrical charge or if the body of the vehicle is subjected to a shock. Airbag safety should include the following precautions. 1. Disarm the airbag(s) if you will be working in the area where a discharged bag could make contact with any part of your body. Consult service information for the exact procedure to follow for the vehicle being serviced. 2. If disposing of an airbag, the usual procedure is to deploy the airbag using a 12 volt power supply, such as a jump-start box, using long wires to connect to the module to ensure a safe deployment. 3. Do not expose an airbag to extreme heat or fire. 4. Always carry an airbag pointing away from your body. 5. Place an airbag module facing upward.
3. Used tires present a fire hazard and, when burned, create a large amount of black smoke that contaminates the air.
DISPOSAL METHODS
Used tires should be disposed of in one
of the following ways. 1. Used tires can be reused until the end of their useful life. 2. Tires can be retreaded. 3. Tires can be recycled or shredded for use in asphalt. 4. Derimmed tires can be sent to a landfill (most landfill operators will shred the tires because it is illegal in many states to landfill whole tires). 5. Tires can be burned in cement kilns or other power plants where the smoke can be controlled. 6. A registered scrap tire handler should be used to transport tires for disposal or recycling.
AIR-CONDITIONING REFRIGERANT OIL DISPOSAL Air-conditioning refrigerant oil contains dissolved refrigerant and is therefore considered to be hazardous waste. This oil must be kept separated from other waste oil or the entire amount of oil must be treated as hazardous. Used refrigerant oil must be sent to a licensed hazardous waste disposal company for recycling or disposal. SEE FIGURE 7–9.
WASTE CHART
All automotive service facilities create some waste and while most of it is handled properly, it is important that all hazardous and nonhazardous waste be accounted for and properly disposed. SEE CHART 7–1 for a list of typical wastes generated at automotive shops, plus a checklist for keeping track of how these wastes are handled.
6. Always follow the manufacturer’s recommended procedure for airbag disposal or recycling, including the proper packaging to use during shipment. 7. Wear protective gloves if handling a deployed airbag. 8. Always wash your hands or body well if exposed to a deployed airbag. The chemicals involved can cause skin irritation and possible rash development.
USED TIRE DISPOSAL ENVIRONMENTAL CONCERN
Used tires are an environmental concern because of several reasons, including the following: 1. In a landfill, they tend to “float” up through the other trash and rise to the surface. 2. The inside of tires traps and holds rainwater, which is a breeding ground for mosquitoes. Mosquito-borne diseases include encephalitis and dengue fever.
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FIGURE 7–9 Air-conditioning refrigerant oil must be kept separated from other oils because it contains traces of refrigerant and must be treated as hazardous waste.
WASTE STREAM
TYPICAL CATEGORY IF NOT MIXED WITH OTHER HAZARDOUS WASTE
IF DISPOSED IN LANDFILL AND NOT MIXED WITH A HAZARDOUS WASTE
IF RECYCLED
Used oil
Used oil
Hazardous waste
Used oil
Used oil filters
Nonhazardous solid waste, if completely drained
Nonhazardous solid waste, if completely drained
Used oil, if not drained
Used transmission fluid
Used oil
Hazardous waste
Used oil
Used brake fluid
Used oil
Hazardous waste
Used oil
Used antifreeze
Depends on characterization
Depends on characterization
Depends on characterization
Used solvents
Hazardous waste
Hazardous waste
Hazardous waste
Used citric solvents
Nonhazardous solid waste
Nonhazardous solid waste
Hazardous waste
Lead-acid automotive batteries
Not a solid waste if returned to supplier
Hazardous waste
Hazardous waste
Shop rags used for oil
Used oil
Depends on used oil characterization
Used oil
Shop rags used for solvent or gasoline spills
Hazardous waste
Hazardous waste
Hazardous waste
Oil spill absorbent material
Used oil
Depends on used oil characterization
Used oil
Spill material for solvent and gasoline
Hazardous waste
Hazardous waste
Hazardous waste
Catalytic converter
Not a solid waste if returned to supplier
Nonhazardous solid waste
Nonhazardous solid waste
Spilled or unused fuels
Hazardous waste
Hazardous waste
Hazardous waste
Spilled or unusable paints and thinners
Hazardous waste
Hazardous waste
Hazardous waste
Used tires
Nonhazardous solid waste
Nonhazardous solid waste
Nonhazardous solid waste
CHART 7–1 Typical wastes generated at auto repair shops and typical category (hazardous or nonhazardous) by disposal method.
TECH TIP Remove Components That Contain Mercury Some vehicles have a placard near the driver’s side door that lists the components that contain the heavy metal, mercury. Mercury can be absorbed through the skin and is a heavy metal that once absorbed by the body does not leave. SEE FIGURE 7–10. These components should be removed from the vehicle before the rest of the body is sent to be recycled to help prevent releasing mercury into the environment. FIGURE 7–10 Placard near driver’s door, including what devices in the vehicle contain mercury.
TECH TIP What Every Technician Should Know The Hazardous Materials Identification Guide (HMIG) is the standard labeling for all materials. The service technician should be aware of the meaning of the label. SEE FIGURE 7–11.
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Hazardous Materials Identification Guide (HMIG) 4 - Extreme 3 - Serious
DEGREE
TYPE HAZARD
HEALTH FLAMMABILITY REACTIVITY PROTECTIVE EQUIPMENT
2 - Moderate 1 - Slight 0 - Minimal
HAZARD RATING AND PROTECTIVE EQUIPMENT Health
Flammable
Reactive
Type of Possible Injury
Susceptibility of materials to burn
Susceptibility of materials to release energy
4
Highly Toxic. May be fatal on short term exposure. Special protective equipment required.
4
Extremely flammable gas or liquid. Flash Point below 73F.
4
Extreme. Explosive at room temperature.
3
Toxic. Avoid inhalation or skin contact.
3
Flammable. Flash Point 73F to 100F.
3
Serious. May explode if shocked, heated under confinement or mixed w/ water.
2
Moderately Toxic. May be harmful if inhaled or absorbed.
2
Combustible. Requires moderate heating to ignite. Flash Point 100F to 200F.
2
Moderate. Unstable, may react with water.
1
Slightly Toxic. May cause slight irritation.
1
Slightly Combustible. Requires strong heating to ignite.
1
Slight. May react if heated or mixed with water.
0
Minimal. All chemicals have a slight degree of toxicity.
0
Minimal. Will not burn under normal conditions.
0
Minimal. Normally stable, does not react with water.
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Ch Go em gg ical les
+
+
+
or
H
D
+
s
S G afet la y ss es
+
+
D Re ust sp ira t
G
C
+
Ap r
S G afet la y ss es S G afet la y ss es
+
+
s
S G afet la y ss es
F
B
S G afet la y ss es
+
A
Fa ce sh iel d
E
S G afet la y ss es
Protective Equipment
X
Ask your supervisor for guidance.
FIGURE 7–11 The Environmental Protection Agency (EPA) Hazardous Materials Identification Guide is a standardized listing of the hazards and the protective equipment needed.
REVIEW QUESTIONS 1. List five common automotive chemicals or products that may be considered hazardous materials.
2. List five precautions to which every technician should adhere when working with automotive products and chemicals.
CHAPTER QUIZ 1. Hazardous materials include all of the following except ______________. a. Engine oil c. Water b. Asbestos d. Brake cleaner 2. To determine if a product or substance being used is hazardous, consult ______________. a. A dictionary b. An MSDS c. SAE standards d. EPA guidelines
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3. Exposure to asbestos dust can cause what condition? a. Asbestosis c. Lung cancer b. Mesothelioma d. All of the above 4. Wetted asbestos dust is considered to be ______________. a. Solid waste c. Toxic b. Hazardous waste d. Poisonous 5. An oil filter should be hot drained for how long before disposing of the filter? a. 30 to 60 minutes c. 8 hours b. 4 hours d. 12 hours
6. Used engine oil should be disposed of by all except the following methods. a. Disposed of in regular trash b. Shipped offsite for recycling c. Burned onsite in a waste oil-approved heater d. Burned offsite in a waste oil-approved heater 7. All of the following are the proper ways to dispose of a drained oil filter except ______________. a. Sent for recycling b. Picked up by a service contract company c. Disposed of in regular trash d. Considered to be hazardous waste and disposed of accordingly
S E C T I O N
III
8. Which act or organization regulates air-conditioning refrigerant? a. Clean Air Act (CAA) b. MSDS c. WHMIS d. Code of Federal Regulations (CFR) 9. Gasoline should be stored in approved containers that include what color(s)? a. A red container with yellow lettering b. A red container c. A yellow container d. A yellow container with red lettering 10. What automotive devices may contain mercury? a. Rear seat video displays c. HID headlights b. Navigation displays d. All of the above
Tools, Shop Equipment, and Measuring
8 Fasteners and Thread Repair
11 Vehicle Lifting and Hoisting
9 Hand Tools
12 Measuring Systems and Tools
10 Power Tools and Shop Equipment
chapter
8
FASTENERS AND THREAD REPAIR
OBJECTIVES: After studying Chapter 8, the reader should be able to: • Explain the terms used to identify bolts and other threaded fasteners. • Explain the strength ratings of threaded fasteners. • Describe the proper use of nonthreaded fasteners. • Discuss how snap rings are used. KEY TERMS: Bolts 58 • Cap screws 58 • Capillary action 64 • Christmas tree clips 62 • Cotter pins 63 • Crest 58 • Die 60 • Grade 58 • Helical insert 64 • Heli-Coil® 65 • Jam nut 63 • Metric bolts 58 • Pal nut 63 • Penetrating oil 64 • Pitch 58 • Pop rivet 63 • Prevailing torque nuts 60 • Self-tapping screw 62 • Snap ring 62 • Stud 58 • Tap 60 • Tensile strength 59 • Threaded insert 65 • UNC (Unified National Coarse) 58 • UNF (Unified National Fine) 58 • Washers 62
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HEAD
ROUND HEAD SCREW
BOLT LENGTH (SHANK)
FLATHEAD CAPSCREW HEX-HEAD SCREW BOLT
THREADS
PITCH (mm)
MINOR DIAMETER
THREAD DEPTH MAJOR DIAMETER
FIGURE 8–1 The dimensions of a typical bolt showing where sizes are measured. The major diameter is called the crest.
TORX® BOLT
ALLEN BOLT
CHEESE HEAD SCREW
PAN HEAD SCREW
FIGURE 8–3 Bolts and screws have many different heads which determine what tool must be used. Bolts are identified by their diameter and length as measured from below the head, and not by the size of the head or the size of the wrench used to remove or install the bolt. Bolts and screws have many different-shaped heads. SEE FIGURE 8–3. Fractional thread sizes are specified by the diameter in fractions of an inch and the number of threads per inch. Typical UNC thread sizes would be 5/16-18 and 1/2-13. Similar UNF thread sizes would be 5/16-24 and1/2-20. SEE CHART 8–1.
METRIC BOLTS FIGURE 8–2 Thread pitch gauge used to measure the pitch of the thread. This bolt has 13 threads to the inch.
THREADED FASTENERS TERMINOLOGY Most of the threaded fasteners used on vehicles are cap screws. They are called cap screws when they are threaded into a casting. Automotive service technicians usually refer to these fasteners as bolts, regardless of how they are used. In this chapter, they are called bolts. Sometimes, studs are used for threaded fasteners. A stud is a short rod with threads on both ends. Often, a stud will have coarse threads on one end and fine threads on the other end. The end of the stud with coarse threads is screwed into the casting. A nut is used on the opposite end to hold the parts together. The fastener threads must match the threads in the casting or nut. The threads may be measured either in fractions of an inch (called fractional) or in metric units. The size is measured across the outside of the threads, called the crest of the thread. SEE FIGURE 8–1. THREAD SIZES
Fractional threads are either coarse or fine. The coarse threads are called Unified National Coarse (UNC), and the fine threads are called Unified National Fine (UNF). Standard combinations of sizes and number of threads per inch (called pitch) are used. Pitch can be measured with a thread pitch gauge as shown in FIGURE 8–2.
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The size of a metric bolt is specified by the letter M followed by the diameter in millimeters (mm) across the outside (crest) of the threads. Typical metric sizes would be M8 and M12. Fine metric threads are specified by the thread diameter followed by X and the distance between the threads measured in millimeters (M8 ⫻ 1.5). SEE FIGURE 8–4.
GRADES OF BOLTS Bolts are made from many different types of steel, and for this reason some are stronger than others. The strength or classification of a bolt is called the grade. The bolt heads are marked to indicate their grade strength. Graded bolts are commonly used in the suspension parts of the vehicle but can be used almost anywhere in the vehicle. The actual grade of bolts is two more than the number of lines on the bolt head. Metric bolts have a decimal number to indicate the grade. More lines or a higher grade number indicate a stronger bolt. Higher grade bolts usually have threads that are rolled rather than cut, which also makes them stronger. SEE FIGURE 8–5. In some cases, nuts and machine screws have similar grade markings. CAUTION: Never use hardware store (nongraded) bolts, studs, or nuts on any vehicle steering, suspension, or brake component. Always use the exact size and grade of hardware that is specified and used by the vehicle manufacturer.
SIZE
THREADS PER INCH NC NF UNC UNF
OUTSIDE DIAMETER INCHES
0 1 1 2 2 3 3 4 4 5 5
.. 64 .. 56 .. 48 .. 40 .. 40 ..
80 .. 72 .. 64 .. 56 .. 48 .. 44
0.0600 0.0730 0.0730 0.0860 0.0860 0.0990 0.0990 0.1120 0.1120 0.1250 0.1250
6 6 8 8 10 10 12 12
32 .. 32 .. 24 .. 24 ..
.. 40 .. 36 .. 32 .. 28
0.1380 0.1380 0.1640 0.1640 0.1900 0.1900 0.2160 0.2160
1/4 1/4 5/16 5/16 3/8 3/8 7/16 7/16 1/2 1/2
20 .. 18 .. 16 .. 14 .. 13 ..
.. 28 .. 24 .. 24 .. 20 .. 20
0.2500 0.2500 0.3125 0.3125 0.3750 0.3750 0.4375 0.4375 0.5000 0.5000
9/16 9/16 5/8 5/8 3/4 3/4 7/8 7/8
12 .. 11 .. 10 .. 9 ..
.. 18 .. 18 .. 16 .. 14
0.5625 0.5625 0.6250 0.6250 0.7500 0.7500 0.8750 0.8750
CHART 8–1
ROLLING THREADS
FIGURE 8–5 Stronger threads are created by cold-rolling a heattreated bolt blank instead of cutting the threads using a die.
TENSILE STRENGTH Graded fasteners have a higher tensile strength than nongraded fasteners. Tensile strength is the maximum stress used under tension (lengthwise force) without causing failure of the fastener. Tensile strength is specified in pounds per square inch (PSI). See the following chart that shows the grade and specified tensile strength. The strength and type of steel used in a bolt is supposed to be indicated by a raised mark on the head of the bolt. The type of mark depends on the standard to which the bolt was manufactured. Most often, bolts used in machinery are made to SAE Standard J429. Metric bolt tensile strength property class is shown on the head of the bolt as a number, such as 4.6, 8.8, 9.8, and 10.9; the higher the number, the stronger the bolt. SEE FIGURE 8–6. SAE Bolt Designations SAE Grade No. Size Range
Tensile Strength, PSI
1
1/4 through 1-1/2
60,000
2
1/4 through 3/4 74,000 60,000 7/8 through 1-1/2
5
1/4 through 1 1-1/8 through 1-1/2
5.2
Head Marking
Low or medium carbon steel
120,000 105,000
Medium carbon steel, quenched & tempered
1/4 through 1
120,000
Low carbon martensite steel*, quenched & tempered
7
1/4 through 1-1/2
133,000
Medium carbon alloy steel, quenched & tempered
8
1/4 through 1-1/2
150,000
Medium carbon alloy steel, quenched & tempered
8.2
1/4 through 1
150,000
Low carbon Martensite steel*, quenched & tempered
The American National System is one method of sizing fasteners.
FIGURE 8–4 The metric system specifies fasteners by diameter, length, and pitch.
Material
*Martensite steel is steel that has been cooled rapidly, thereby increasing its hardness. It is named after a German metallurgist, Adolf Martens.
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4.6
60,000
8.8
120,000
9.8
130,000
10.9
150,000
METRIC CLASS APPROXIMATE MAXIMUM POUND FORCE PER SQUARE INCH
FIGURE 8–7 Types of lock nuts. On the left, a nylon ring; in the center, a distorted shape; and on the right, a castle for use with a cotter key.
FIGURE 8–6 Metric bolt (cap screw) grade markings and approximate tensile strength.
TAP
TECH TIP A 1/2 In. Wrench Does Not Fit a 1/2 In. Bolt A common mistake made by persons new to the automotive field is to think that the size of a bolt or nut is the size of the head. The size of the bolt or nut (outside diameter of the threads) is usually smaller than the size of the wrench or socket that fits the head of the bolt or nut. Examples are given in the following table. Wrench Size
Thread Size
7/16 in. 1/2 in. 9/16 in. 5/8 in. 3/4 in. 10 mm 12 mm or 13 mm* 14 mm or 17 mm*
1/4 in. 5/16 in. 3/8 in. 7/16 in. 1/2 in. 6 mm 8 mm 10 mm
FIGURE 8–8 A typical bottoming tap used to create threads in holes that are not open, but stop in a casting, such as an engine block.
TAPS AND DIES Taps and dies are used to cut threads. Taps are used to cut threads in holes drilled to an exact size depending on the size of the tap. A die is used to cut threads on round rods or studs. Most taps and dies come as a complete set for the most commonly used fractional and metric threads.
*European (Système International d’Unités-SI) metric.
HINT: An open-end wrench can be used to gauge bolt sizes. A 3/8 in. wrench will fit the threads of a 3/8 in. bolt.
NUTS Most nuts used on cap screws have the same hex size as the cap screw head. Some inexpensive nuts use a hex size larger than the cap screw head. Metric nuts are often marked with dimples to show their strength. More dimples indicate stronger nuts. Some nuts and cap screws use interference fit threads to keep them from accidentally loosening. This means that the shape of the nut is slightly distorted or that a section of the threads is deformed. Nuts can also be kept from loosening with a nylon washer fastened in the nut or with a nylon patch or strip on the threads. SEE FIGURE 8–7. NOTE: Most of these “locking nuts” are grouped together and are commonly referred to as prevailing torque nuts. This means that the nut will hold its tightness or torque and not loosen with movement or vibration. Most prevailing torque nuts should be replaced whenever removed to ensure that the nut will not loosen during service. Always follow the manufacturer’s recommendations. Anaerobic sealers, such as Loctite®, are used on the threads where the nut or cap screw must be both locked and sealed.
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TAPS
There are two commonly used types of taps, including:
Taper tap. This is the most commonly used tap and is designed to cut threads by gradually enlarging the threaded hole.
Bottoming tap. This tap has a flat bottom instead of a tapered tip to allow it to cut threads to the bottom of a drilled hole. SEE FIGURE 8–8.
All taps must be used in the proper size hole called a “tap drill size.” This information is often stamped on the tap itself or in a chart that is included with a tap and die tool set. SEE FIGURE 8–9.
DIES A die is a hardened steel round cutter with teeth on the inside of the center hole. SEE FIGURE 8–10. A die is rotated using a die handle over a rod to create threads. PROPER USE OF TAPS AND DIES
Taps and dies are used to cut threads on rods in the case of a die or in a hole for a tap. A small tap can be held using a T-handle tap wrench but for larger taps a tap handle is needed to apply the needed force to cut threads. SEE FIGURES 8–11A AND 8–11B. TAP USAGE. Be sure that the hole is the correct size for the tap and start by inserting the tap straight into the hole. Lubricate the tap using tapping lubricant. Rotate the tap about one full turn clockwise, then reverse the direction of the tap one-half turn to break the chip that was created. Repeat the procedure until the hole is completely threaded.
DIE HANDLE
FIGURE 8–12 A die handle used to rotate a die while cutting threads on a metal rod.
FIGURE 8–13 A typical metric thread pitch gauge. FIGURE 8–9 Many taps, especially larger ones, have the tap drill size printed on the top. DIE
FIGURE 8–10 A die is used to cut threads on a metal rod. T-HANDLE TAP WRENCH
FIGURE 8–14 A thread chaser is shown at the top compared to a tap on the bottom. A thread chaser is used to clean threads without removing metal.
THREAD PITCH GAUGE (a) HAND TAP WRENCH
(b)
FIGURE 8–11 (a) A T-handle is used to hold and rotate small taps. (b) A tap wrench is used to hold and drive larger taps. DIE USAGE. A die should be used on the specified diameter rod for the size of the thread. Install the die securely into the die handle. SEE FIGURE 8–12. Lubricate the die and the rod and place the die onto the end of the rod to be threaded. Rotate the die handle one full turn clockwise, then reverse the direction and rotate the die handle about a half turn counterclockwise to break the chip that was created. Repeat the process until the threaded portion has been completed.
A thread pitch gauge is a hand tool that has the outline of various thread sizes machined on stamped blades. To determine the thread pitch size of a fastener, the technician matches the thread of the thread pitch gauge to the threads of the fastener. SEE FIGURE 8–13.
?
FREQUENTLY ASKED QUESTION
What Is the Difference Between a Tap and a Thread Chaser? A tap is a cutting tool and is designed to cut new threads. A thread chaser has more rounded threads and is designed to clean dirty threads without removing metal. Therefore, when cleaning threads, it is best to use a thread chaser rather than a tap to prevent the possibility of removing metal, which would affect the fit of the bolt being installed. SEE FIGURE 8–14
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PAN
ROUND
FLAT
HEX NUT
OVAL
HEXAGON
JAM NUT
FLAT WASHER
TRUSS
NYLON CASTLE LOCK NUT NUT
LOCK WASHER
STAR WASHER
ACORN NUT
STAR WASHER
FIGURE 8–16 Various types of nuts (top) and washers (bottom) serve different purposes and all are used to secure bolts or cap screws.
FIGURE 8–15 Sheet metal screws come with many head types.
SHEET METAL SCREWS Sheet metal screws are fully threaded screws with a point for use in sheet metal. Also called self-tapping screws, they are used in many places on the vehicle, including fenders, trim, and door panels. SEE FIGURE 8–15. These screws are used in unthreaded holes and the sharp threads cut threads as they are installed. This makes for a quick and easy installation when installing new parts, but the sheet metal screw can easily strip out the threads when used on the same part over and over, so care is needed. When reinstalling self-tapping screws, first turn the screw lightly backwards until you feel the thread drop into the existing thread in the screw hole. Then, turn the screw in; if it threads in easily, continue to tighten the screw. If the screw seems to turn hard, stop and turn it backwards about another half turn to locate the existing thread and try again. This technique can help prevent stripped holes in sheet metal and plastic parts. Sheet metal screws are sized according to their major thread diameter.
Size
Diameter Decimal (inch)
Diameter Nearest Fraction Inch
4 6 8 10 12 14
0.11 0.14 0.17 0.19 0.22 0.25
7/64 9/64 11/64 3/16 7/32 1/4
WASHERS Washers are often used under cap screw heads and under nuts. SEE FIGURE 8–16. Plain flat washers are used to provide an even clamping load around the fastener. Lock washers are added to prevent accidental loosening. In some accessories, the washers are locked onto the nut to provide easy assembly.
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Flat washers are placed underneath a nut to spread the load over a wide area and prevent gouging of the material. However, flat washers do not prevent a nut from loosening. Lock washers are designed to prevent a nut from loosening. Spring-type lock washers resemble a loop out of a coil spring. As the nut or bolt is tightened, the washer is compressed. The tension of the compressed washer holds the fastener firmly against the threads to prevent it from loosening. Lock washers should not be used on soft metal such as aluminum. The sharp ends of the steel washers would gouge the aluminum badly, especially if they are removed and replaced often. Another type of locking washer is the star washer. The teeth on a star washer can be external or internal, and they bite into the metal because they are twisted to expose their edges. Star washers are used often on sheet metal or body parts. They are seldom used on engines. The spring steel lock washer also uses the tension of the compressed washer to prevent the fastener from loosening. The waves in this washer make it look like a distorted flat washer.
SNAP RINGS AND CLIPS SNAP RINGS
Snap rings are not threaded fasteners, but instead attach with a springlike action. Snap rings are constructed of spring steel and are used to attach parts without using a threaded fastener. There are several different types of snap rings and most require the use of a special pair of pliers, called snap ring pliers, to release or install. The types of snap rings include:
Expanding (internal)
Contracting (external)
E-clip
C-clip
Holeless snap rings in both expanding and contracting styles.
SEE FIGURE 8–17.
DOOR PANEL CLIPS Interior door panels and other trim pieces are usually held in place with plastic clips. Due to the tapered and fluted shape, these clips are often called Christmas tree clips. SEE FIGURE 8–18. A special tool is often used to remove interior door panels without causing any harm. SEE FIGURE 8–19. CAUTION: Use extreme care when removing panels that use plastic or nylon clips. It is very easy to damage the door panel or clip during removal.
EXPANDING EXPANDING OR INTERNAL OR EXTERNAL
E-CLIP
EXPANDING CONTRACTING OR INTERNAL OR EXTERNAL
C-CLIP
FIGURE 8–17 Some different types of snap rings. An internal snap ring fits inside of a housing or bore, into a groove. An external snap ring fits into a groove on the outside of a shaft or axle. An E-clip fits into a groove in the outside of a shaft. A C-clip shown is used to retain a window regulator handle on its shaft.
CLEVIS
TAPER
ROLL
HAIR PIN
COTTER
FIGURE 8–20 Pins come in various types.
BLIND (POP)
STRAIGHT
PLASTIC
HIGH-STRENGTH BLIND
FIGURE 8–21 Various types of rivets. FIGURE 8–18 A typical door panel retaining clip. HEXAGON
12 POINT
SELF-THREADING
CAGE
SQUARE SELF-LOCKING
PAL
CASTLE
CAP
WING
FIGURE 8–22 All of the nuts shown are used by themselves except for the pal nut, which is used to lock another nut to a threaded fastener so they will not be loosened by vibration.
FIGURE 8–19 Plastic or metal trim tools are available to help the technician remove interior door panels and other trim without causing harm.
PINS
Cotter pins, also called a cotter key, are used to keep linkage or a threaded nut in place or to keep it retained. The word cotter is an Old English verb meaning “to close or fasten.” There are many other types of pins used in vehicles, including clevis pins, roll pins, and hair pins. SEE FIGURE 8–20. Pins are used to hold together shafts and linkages, such as shift linkages and cable linkages. The clevis pin is held in place with a cotter pin, while the taper and roll pins are driven in and held by friction. The hair pin snaps into a groove on a shaft.
RIVETS
Rivets are used in many locations to retain components, such as window mechanisms, that do not require routine removal and/or do not have access to the back side for a nut. A drill is usually used to remove a rivet and a rivet gun is needed to properly install
a rivet. Some rivets are plastic and are used to hold some body trim pieces. The most common type of rivet is called a pop rivet because as the rivet tool applies a force to the shaft of the pop rivet, it causes the rivet to expand and tighten the two pieces together. When the shaft of the rivet, which looks like a nail, is pulled to its maximum, the shaft breaks, causing a “pop” sound. Rivets may be used in areas of the vehicle where a semipermanent attachment is needed and in places where there is no access to the back side of the workpiece. They are installed using a rivet gun or by peening with a ball-peen hammer. SEE FIGURE 8–21. Both types of blind rivets require the use of a rivet gun to install. The straight rivet is placed through the workpieces and then peened over with a ball-peen hammer or an air-operated tool. The plastic rivet is used with a rivet gun to install some body trim parts.
LOCKING NUTS Some nuts, called jam nuts, are used to keep bolts and screws from loosening. Jam nuts screw on top of a regular nut and jam against the regular nut to prevent loosening. A jam nut is so called because of its intended use, rather than a special design. Some jam nuts are thinner than a standard nut. Jam nuts are also called pal nuts. SEE FIGURE 8–22.
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CASTLELLATED NUT
FIGURE 8–24 Helical inserts look like small, coiled springs. The outside is a thread to hold the coil in the hole, and the inside is threaded to fit the desired fastener. HOLE IN THREADED STUD
COTTER PIN
FIGURE 8–23 A castellated nut is locked in place with a cotter pin. There are also self-locking nuts of various types. Some have threads that are bent inward to grip the threads of the bolt. Some are oval-shaped at one end to fit tightly on a bolt. Fiber lock nuts have a fiber insert near the top of the nut or inside it; this type of nut is also made with a plastic or nylon insert. When the bolt turns through the nut, it cuts threads in the fiber or plastic. This puts a drag on the threads that prevents the bolt from loosening. One of the oldest types of retaining nuts is the castle nut. It looks like a small castle, with slots for a cotter pin. A castellated nut is used on a bolt that has a hole for the cotter pin. SEE FIGURE 8–23.
HOW TO AVOID BROKEN FASTENERS Try not to break, strip, or round off fasteners in the first place. There are several ways that you can minimize the number of fasteners you damage. First, never force fasteners loose during disassembly. Taking a few precautionary steps will often prevent damage. If a bolt or nut will not come loose with normal force, try tightening it in slightly and then backing it out. Sometimes turning the fastener the other way will break corrosion loose, and the fastener will then come out easily. Another method that works well is to rest a punch on the head of a stubborn bolt and strike it a sharp blow with a hammer. Often this method will break the corrosion loose.
LEFT-HANDED THREADS Although rare, left-handed fasteners are occasionally found on engine assemblies. These fasteners will loosen when you turn them clockwise, and tighten when you turn them counterclockwise. Left-handed fasteners are used to fasten parts to the ends of rotating assemblies that turn counterclockwise, such as crankshafts and camshafts. Most automobile engines do not use left-handed threads; however, they will be found on many older motorcycle engines. Some left-handed fasteners are marked with an “L” on the bolt head for easy identification, others are not. Left-handed threads are also found inside some transaxles. PENETRATING OIL Penetrating oil is a lightweight lubricant similar to kerosene, which soaks into small crevices in the threads by capillary action. The chemical action of penetrating oils helps to
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break up and dissolve rust and corrosion. The oil forms a layer of boundary lubrication on the threads to reduce friction and make the fastener easier to turn. For best results, allow the oil time to soak in before removing the nuts and bolts. To increase the effectiveness of penetrating oil, tap on the bolt head or nut with a hammer, or alternately work the fastener back and forth with a wrench. This movement weakens the bond of the corrosion and lets more of the lubricant work down into the threads.
PROPER TIGHTENING Proper tightening of bolts and nuts is critical for proper clamping force, as well as to prevent breakage. All fasteners should be tightened using a torque wrench. A torque wrench allows the technician to exert a known amount of torque to the fasteners. However, rotating torque on a fastener does not mean clamping force because up to 80% of the torque used to rotate a bolt or nut is absorbed by friction by the threads. Therefore, for accurate tightening, two things must be performed:
The threads must be clean and lubricated if service information specifies that they be lubricated.
Always use a torque wrench to not only ensure proper clamping force, but also to ensure that all fasteners are tightened the same.
THREAD REPAIR INSERTS Thread repair inserts are used to replace the original threaded hole when it has become damaged beyond use. The original threaded hole is enlarged and tapped for threads and a threaded insert is installed to restore the threads to the original size.
HELICAL INSERTS A helical insert looks like a small, stainlesssteel spring. SEE FIGURE 8–24. To install a helical insert, a hole must be drilled to a specified oversize, and then it is tapped with a special tap designed for the thread inserts. The insert is then screwed into the hole. SEE FIGURE 8–25. The insert stays in the casting as a permanent repair and bolts can be removed and replaced without disturbing the insert. One advantage of a helical insert is that the original bolt can be used because the internal threads are the same size. When correctly installed, an insert is often stronger than the original threads, especially in aluminum castings. Some vehicle manufacturers, such as BMW, specify that the threads be renewed using an insert if the cylinder head has
FIGURE 8–25 The insert provides new, stock-size threads inside an oversize hole so that the original fastener can be used.
FIGURE 8–27 This solid-bushing insert is threaded on the outside, to grip the workpiece. The inner threads match the desired bolt size.
6. Remove the mandrel by unscrewing it from the insert, and then use a small punch or needle-nose pliers to break off the tang at the base of the insert. Never leave the tang in the bore. The finished thread is ready for use immediately.
THREADED INSERTS
FIGURE 8–26 Heli-Coil® kits, available in a wide variety of sizes, contain everything needed to repair a damaged hole back to its original size.
to be removed and reinstalled. Plus many high-performance engine rebuilders install inserts in blocks, manifolds, and cylinder heads as a precaution. One of the best known of the helical fasteners is the Heli-Coil®, manufactured by Heli-Coil® Products. To install Heli-Coil® inserts, you will need to have a thread repair kit. The kit includes a drill bit, tap, installation mandrel, and inserts. Repair kits are available for a wide variety of diameters and pitch to fit both American Standard and metric threads. A simple kit contains the tooling for one specific thread size. Master kits that cover a range of sizes are also available. Installing an insert is similar to tapping new threads. A summary of the procedures includes:
Threaded inserts are tubular, casehardened, solid steel wall pieces that are threaded inside and outside. The inner thread of the insert is sized to fit the original fastener of the hole to be repaired. The outer thread design will vary. These may be self-tapping threads that are installed in a blank hole, or machine threads that require the hole to be tapped. Threaded inserts return a damaged hole to original size by replacing part of the surrounding casting so drilling is required. Most inserts fit into three categories.
Self-tapping
Solid-bushing
Key-locking
SELF-TAPPING INSERTS The external threads of a selftapping insert are designed to cut their own way into a casting. This eliminates the need of running a tap down the hole. To install a typical self-tapping insert, follow this procedure. 1. Drill out the damaged threads to open the hole to the proper size, using the specified size drill bit. 2. Select the proper insert and mandrel. As with Heli-Coils®, the drill bit, inserts, and mandrel are usually available as a kit.
1. Select the Heli-Coil® kit designed for the specific diameter and thread pitch of the hole to be repaired. SEE FIGURE 8–26.
3. Thread the insert onto the mandrel. Use a tap handle or wrench to drive the insert into the hole. Because the insert will cut its own path into the hole, it may require a considerable amount of force to drive the insert in.
2. Use the drill bit supplied with the kit. The drill size is also specified on the Heli-Coil® tap, to open up the hole to the necessary diameter and depth.
4. Thread the insert in until the nut or flange at the bottom of the mandrel touches the surface of the workpiece. This is the depth stop to indicate the insert is seated.
3. Tap the hole with the Heli-Coil® tap, being sure to lubricate the tap. Turn it in slowly and rotate counterclockwise occasionally to break the chip that is formed.
5. Hold the nut or flange with a wrench, and turn the mandrel out of the insert. The threads are ready for immediate use.
4. Thread an insert onto the installation mandrel until it seats firmly. Apply a light coating of the recommended thread locking compound to the external threads of the insert. 5. Use the mandrel to screw the insert into the tapped hole. Once started, spring tension prevents the insert from unscrewing. Stop when the top of the insert is 1/4 to 1/2 turn below the surface.
SOLID-BUSHING INSERTS
The external threads of solidbushing inserts are ground to a specific thread pitch, so you will have to run a tap into the hole. SEE FIGURE 8–27. Some inserts use a machine thread so a standard tap can be used; others have a unique thread and you have to use a special tap. The thread inserts come with a matching installation kit. SEE FIGURE 8–28.
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FIGURE 8–30 Use a special tap for the insert. (a)
(b)
(c)
(d)
(e)
FIGURE 8–28 A Timesert® kit includes the drill (a), the recess cutter (b), a special tap (c), the installer (d), and the Timesert® threaded bushing (e).
FIGURE 8–31 Put some thread-locking compound on the insert.
5. Remove the installation driver, and the new threads are ready for service with the original fastener. FIGURE 8–29 Drill out the damaged threads with the correct bit. To install threaded inserts, follow this procedure. 1. Drill out the damaged threads to open the hole to the proper size. The drill bit supplied with the kit must be the one used because it is properly sized to the tap. SEE FIGURE 8–29. 2. Cut the recess in the top of the hole with the special tool, then clean the hole with a brush or compressed air.
KEY-LOCKING INSERTS Key-locking inserts are similar to solid-bushing inserts, but are held in place by small keys. After the insert has been installed, the keys are driven into place—perpendicular to the threads—to keep the insert from turning out. A typical installation procedure includes the following steps. 1. Drill out the damaged thread with the specified drill size. 2. Tap the drilled hole with the specified tap.
3. Use the previously detailed tapping procedures to thread the hole. SEE FIGURE 8–30. Be sure to tap deep enough; the top of the insert must be flush with the casting surface.
3. After putting thread locking compound on the insert, use the mandrel to screw the insert into the tapped hole until it is slightly below the surface. SEE FIGURE 8–31. The keys act as a depth stop and prevent the insert from turning.
4. Thread the insert onto the installation driver, using the driver to screw the insert into the hole. Some inserts require that a thread-locking compound be applied; others go in dry.
4. Drive the keys down using the driver supplied with the insert kit. Be sure the keys are flush with the top of the insert. SEE FIGURES 8–32 AND 8–33.
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FIGURE 8–32 Use the driver to drive the keys down flush with the surface of the workpiece.
FIGURE 8–33 The insert and insert locks should be below the surface of the workpiece.
REVIEW QUESTIONS 1. What is the difference between a bolt and a stud?
4. How do prevailing torque nuts work?
2. How is the size of a metric bolt expressed?
5. How are threaded inserts installed?
3. What is meant by the grade of a threaded fastener?
CHAPTER QUIZ 1. The thread pitch of a bolt is measured in what units? a. Millimeters b. Threads per inch c. Fractions of an inch d. Both a and b 2. Technician A says that the diameter of a bolt is the same as the wrench size used to remove or install the fastener. Technician B says that the length is measured from the top of the head of the bolt to the end of the bolt. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 3. The grade of a fastener, such as a bolt, is a measure of its ______________. a. Tensile strength c. Finish b. Hardness d. Color 4. Which of the following is a metric bolt? a. 5/16 ⫺ 18 c. M12 ⫻ 1.5 b. 1/2 ⫺ 20 d. 8 mm 5. A bolt that is threaded into a casting is often called a ______________. a. Stud c. Block bolt b. Cap screw d. Crest bolt
6. The marks (lines) on the heads of bolts indicate ______________. a. Size c. Tensile strength b. Grade d. Both b and c 7. A bolt that requires a 1/2 in. wrench to rotate is usually what size when measured across the threads? a. 1/2 in. c. 3/8 in. b. 5/16 in. d. 7/16 in. 8. A screw that can make its own threads when installed is called a ______________ screw. a. Sheet metal b. Tapered c. Self-tapping d. Both a and c 9. All of the following are types of clips except ______________. a. E-clip b. Cotter c. C-clip d. Internal 10. What type of fastener is commonly used to retain interior door panels? a. Christmas tree clips b. E-clips c. External clips d. Internal clips
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chapter
HAND TOOLS
9 OBJECTIVES: After studying Chapter 9, the reader should be able to: • Describe what tool is the best to use for each job. • Discuss how to safely use hand tools. • Explain the difference between the brand name (trade name) and the proper name for tools. • Explain how to maintain hand tools. KEY TERMS: Adjustable wrench 68 • Aviation tin snips 75 • Beam-type torque wrench 70 • Box-end wrench 68 • Breaker bar (flex handle) 69 • Cheater bar 80 • Chisel 76 • Clicker-type torque wrench 70 • Close-end wrench 68 • Cold chisel 76 • Combination wrench 68 • Crowfoot socket 70 • Dead-blow hammer 73 • Diagonal (side-cut or dike) pliers 73 • Double-cut file 75 • Drive size 70 • Easy out 77 • Extension 70 • Files 75 • Fitting wrench 68 • Flare-nut wrench 68 • Flat-tip (straight blade) screwdriver 72 • Hacksaw 77 • Locking pliers 74 • Multigroove adjustable pliers 73 • Needle-nose pliers 74 • Nut splitter 76 • Offset left aviation snip 75 • Offset right aviation snip 75 • Open-end wrench 68 • Punch 75 • Ratchet 69 • Removers 76 • Screwdriver 72 • Seal driver 79 • Seal puller 79 • Single-cut file 75 • Slip-joint pliers 73 • Snap-ring pliers 75 • Socket 69 • Socket adapter 71 • Straight cut aviation snip 75 • Stud removal tool 76 • Stud remover 76 • Tin snips 75 • Torque wrench 70 • Tube-nut wrench 68 • Universal joint 70 • Utility knife 75 • Vise-Grip® 74 • Water pump pliers 73 • Wrench 68
WRENCHES Wrenches are the most used hand tool by service technicians. Most wrenches are constructed of forged alloy steel, usually chromevanadium steel. SEE FIGURE 9–1. After the wrench is formed, it is hardened, tempered to reduce brittleness, and then chrome plated. Wrenches are available in both fractional and metric sizes. There are several types of wrenches.
OPEN-END WRENCH An open-end wrench is often used to loosen or tighten bolts or nuts that do not require a lot of torque. An open-end wrench can be easily placed on a bolt or nut with an angle of 15 degrees, which allows the wrench to be flipped over and used again to continue to rotate the fastener. The major disadvantage of an open-end wrench is the lack of torque that can be applied due to the fact that the open jaws of the wrench only contact two flat surfaces of the fastener. An open-end wrench has two different sizes, one at each end. SEE FIGURE 9–2. BOX-END WRENCH A box-end wrench is placed over the top of the fastener and grips the points of the fastener. A box-end wrench is angled 15 degrees to allow it to clear nearby objects. SEE FIGURE 9–3. Therefore, a box-end wrench should be used to loosen or to tighten fasteners. A box-end wrench is also called a close-end wrench. A box-end wrench has two different sizes, one at each end. SEE FIGURE 9–4. COMBINATION WRENCH
Most service technicians purchase combination wrenches, which have the open end at one end and the same size box end on the other. SEE FIGURE 9–5.
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FIGURE 9–1 A forged wrench after it has been forged but before the flashing, extra material around the wrench, has been removed.
A combination wrench allows the technician to loosen or tighten a fastener using the box end of the wrench, turn it around, and use the open end to increase the speed of rotating the fastener.
ADJUSTABLE WRENCH
An adjustable wrench is often used where the exact size wrench is not available or when a large nut, such as a wheel spindle nut, needs to be rotated but not tightened. An adjustable wrench should not be used to loosen or tighten fasteners because the torque applied to the wrench can cause the movable jaws to loosen their grip on the fastener, causing it to become rounded. SEE FIGURE 9–6.
LINE WRENCHES
Line wrenches are also called flare-nut wrenches, fitting wrenches, or tube-nut wrenches and are designed to grip almost all the way around a nut used to retain a fuel or refrigerant line, and yet be able to be installed over the line. SEE FIGURE 9–7. SAFE USE OF WRENCHES. Wrenches should be inspected before use to be sure they are not cracked, bent, or damaged. All wrenches should be cleaned after use before being returned to the toolbox.
1/2
6
9/1
15˚
15˚
FIGURE 9–2 A typical open-end wrench. The size is different on each end and notice that the head is angled 15 degrees at each end.
FIGURE 9–3 A typical box-end wrench is able to grip the bolt or nut at points completely around the fastener. Each end is a different size.
FIGURE 9–7 The end of a typical line wrench, which shows that it is capable of grasping most of the head of the fitting.
ANGLED SHANK RATCHET REVERSING LEVER 15˚
FIGURE 9–4 The end of a box-end wrench is angled 15 degrees to allow clearance for nearby objects or other fasteners. BOX END OPEN END
1/2 - 3/4 INCH SQUARE DRIVE LUG
FIGURE 9–8 A typical ratchet used to rotate a socket. A ratchet makes a ratcheting noise when it is being rotated in the opposite direction from loosening or tightening. A knob or lever on the ratchet allows the user to switch directions.
FIGURE 9–5 A combination wrench has an open end at one end and a box end at the other with the same size at each end.
OVERALL LENGTH
FIGURE 9–9 A typical flex handle used to rotate a socket, also called a breaker bar because it usually has a longer handle than a ratchet and, therefore, can be used to apply more torque to a fastener than a ratchet.
FIGURE 9–6 An adjustable wrench. Adjustable wrenches are sized by the overall length of the wrench and not by how far the jaws open. Common sizes of adjustable wrenches include 8, 10, and 12 in. Always use the correct size of wrench for the fastener being loosened or tightened to help prevent the rounding of the flats of the fastener. When attempting to loosen a fastener, pull a wrench—do not push a wrench. If a wrench is pushed, your knuckles can be hurt when forced into another object if the fastener breaks loose.
RATCHETS, SOCKETS, AND EXTENSIONS A socket fits over the fastener and grips the points and/or flats of the bolt or nut. The socket is rotated (driven) using either a long bar called a breaker bar (flex handle) or a ratchet. SEE FIGURES 9–8 AND 9–9.
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1/2" 3/8" 1/4"
FIGURE 9–10 The most commonly used socket drive sizes include 1/4 in., 3/8 in., and 1/2 in. drive.
6-POINT SOCKET
12-POINT SOCKET
FIGURE 9–13 Using a torque wench to tighten connecting rod nuts on an engine.
NUT
FIGURE 9–11 A 6-point socket fits the head of the bolt or nut on all sides. A 12-point socket can round off the head of a bolt or nut if a lot of force is applied. FIGURE 9–14 A beam-type torque wrench that displays the torque reading on the face of the dial. The beam display is read as the beam deflects, which is in proportion to the amount of torque applied to the fastener.
TECH TIP Right to Tighten FIGURE 9–12 A crowfoot socket is designed to reach fasteners using a ratchet or breaker bar with an extension.
A ratchet turns the socket in only one direction and allows the rotating of the ratchet handle back and forth in a narrow space. Socket extensions and universal joints are also used with sockets to allow access to fasteners in restricted locations. Sockets are available in various drive sizes, including 1/4 in., 3/8 in., and 1/2 in. sizes for most automotive use. SEE FIGURES 9–10 AND 9–11. Many heavy-duty truck and/or industrial applications use 3/4 in. and 1 in. sizes. The drive size is the distance of each side of the square drive. Sockets and ratchets of the same size are designed to work together.
CROWFOOT SOCKETS A crowfoot socket is a socket that is an open-end or line wrench to allow access to fasteners that cannot be reached using a conventional wrench. SEE FIGURE 9–12. Crowfoot sockets are available in the following categories.
Fractional inch open-end wrench
Metric open-end wrench
Fractional line wrench
Metric line wrench
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It is sometimes confusing which way to rotate a wrench or screwdriver, especially when the head of the fastener is pointing away from you. To help visualize while looking at the fastener, say “righty tighty, lefty loosey.”
TORQUE WRENCHES
Torque wrenches are socket turning handles that are designed to apply a known amount of force to the fastener. There are two basic types of torque wrenches. 1. A clicker-type torque wrench is first set to the specified torque and then it “clicks” when the set torque value has been reached. When force is removed from the torque wrench handle, another click is heard. The setting on a clicker-type torque wrench should be set back to zero after use and checked for proper calibration regularly. SEE FIGURE 9–13. 2. A beam- or dial-type torque wrench is used to measure torque, but instead of presetting the value, the actual torque is displayed on the dial of the wrench as the fastener is being tightened. Beam-type torque wrenches are available in 1/4 in., 3/8 in., and 1/2 in. drives and both English and metric units. SEE FIGURE 9–14.
SAFE USE OF SOCKETS AND RATCHETS. Always use the proper size socket that correctly fits the bolt or nut. All sockets and ratchets
?
FREQUENTLY ASKED QUESTION
Is It Lb-Ft or Ft-Lb of Torque? The unit for torque is expressed as a force times the distance (leverage) from the object. Therefore, the official unit for torque is lb-ft (pound-feet) or newton-meters (a force times a distance). However, it is commonly expressed in ft-lb and even some torque wrenches are labeled with this unit.
TECH TIP Double-Check the Specifications Misreading torque specifications is easy to do but can have serious damaging results. Specifications for fasteners are commonly expressed lb-ft. Many smaller fasteners are tightened to specifications expressed in lb-in. 1 lb-ft ⫽ 12 lb-in.
FIGURE 9–15 Torque wrench calibration checker.
Therefore, if a fastener were to be accidentally tightened to 24 lb-ft instead of 24 lb-in., the actual torque applied to the fastener will be 288 lb-in. instead of the specified 24 lb-in. This extra torque will likely break the fastener, but it could also warp or distort the part being tightened. Always double-check the torque specifications.
REGULAR SOCKET DEEP SOCKET
TECH TIP Use Socket Adapters with Caution
FIGURE 9–16 Deep sockets allow access to the nut that has a stud plus other locations needing great depth, such as spark plugs.
TECH TIP Check Torque Wrench Calibration Regularly Torque wrenches should be checked regularly. For example, Honda has a torque wrench calibration setup at each of their training centers. It is expected that a torque wrench be checked for accuracy before every use. Most experts recommend that torque wrenches be checked and adjusted as needed at least every year and more often if possible. SEE FIGURE 9–15.
Socket adapters are available and can be used for different drive size sockets on a ratchet. Combinations include: • • • •
1/4 in. drive—3/8 in. sockets 3/8 in. drive—1/4 in. sockets 3/8 in. drive—1/2 in. sockets 1/2 in. drive—3/8 in. sockets
Using a larger drive ratchet or breaker bar on a smaller size socket can cause the application of too much force to the socket, which could crack or shatter. Using a smaller size drive tool on a larger socket will usually not cause any harm, but would greatly reduce the amount of torque that can be applied to the bolt or nut.
TECH TIP
should be cleaned after use before being placed back into the toolbox. Sockets are available in short and deep well designs. SEE FIGURE 9–16. Also select the appropriate drive size. For example, for small work, such as on the dash, select a 1/4 in. drive. For most general service work, use a 3/8 in. drive and for suspension and steering and other large fasteners, select a 1/2 in. drive. When loosening a fastener, always pull the ratchet toward you rather than push it outward.
Avoid Using “Cheater Bars” Whenever a fastener is difficult to remove, some technicians will insert the handle of a ratchet or a breaker bar into a length of steel pipe. The extra length of the pipe allows the technician to exert more torque than can be applied using the drive handle alone. However, the extra torque can easily overload the socket and ratchet, causing them to break or shatter, which could cause personal injury.
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BLADE WIDTH
FIGURE 9–17 A flat-tip (straight blade) screwdriver. The width of the blade should match the width of the slot in the fastener being loosened or tightened.
FIGURE 9–18 Two stubby screwdrivers that are used to access screws that have limited space above. A straight blade is on top and a #2 Phillips screwdriver is on the bottom.
FIGURE 9–19 An offset screwdriver is used to install or remove fasteners that do not have enough space above to use a conventional screwdriver.
FIGURE 9–20 An impact screwdriver used to remove slotted or Phillips head fasteners that cannot be broken loose using a standard screwdriver.
?
FREQUENTLY ASKED QUESTION
What Are Torx and Robertson Screwdrivers?
SCREWDRIVERS Many smaller fasteners are removed and installed by using a screwdriver. Screwdrivers are available in many sizes and tip shapes. The most commonly used screwdriver is called a flat tip or straight blade. Flat-tip screwdrivers are sized by the width of the blade and this width should match the width of the slot in the screw. SEE FIGURE 9–17. CAUTION: Do not use a screwdriver as a pry tool or as a chisel. Always use the proper tool for each application. Another type of commonly used screwdriver is called a Phillips screwdriver, named for Henry F. Phillips, who invented the crosshead screw in 1934. Due to the shape of the crosshead screw and screwdriver, a Phillips screw can be driven with more torque than can be achieved with a slotted screw. A Phillips head screwdriver is specified by the length of the handle and the size of the point at the tip. A #1 tip has a sharp point, a #2 tip is the most commonly used, and a #3 tip is blunt and is only used for larger sizes of Phillips head fasteners. For example, a #2 ⫻ 3 in. Phillips screwdriver would typically measure 6 in. from the tip of the blade to the end of the handle (3 in. long handle and 3 in. long blade) with a #2 tip. Both straight blade and Phillips screwdrivers are available with a short blade and handle for access to fasteners with limited room. SEE FIGURE 9–18.
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A Torx is a six-pointed star-shaped tip that was developed by Camcar (formerly Textron) to offer greater loosening and tightening torque than is possible with a straight (flat tip) or Phillips screwdriver. Torx is commonly used in the automotive field for fastening of many components. P. L. Robertson invented the Robertson screw and screwdriver in 1908, which uses a square-shaped tip with a slight taper. The Robertson screwdriver uses color-coded handles because different size screws require different tip sizes. Robertson screws are commonly used in Canada and in the recreational vehicle (RV) industry in the United States.
OFFSET SCREWDRIVERS
Offset screwdrivers are used in places where a conventional screwdriver cannot fit. An offset screwdriver is bent at the ends and is used similar to a wrench. Most offset screwdrivers have a straight blade at one end and a Phillips end at the opposite end. SEE FIGURE 9–19.
IMPACT SCREWDRIVER
An impact screwdriver is used to break loose or tighten a screw. A hammer is used to strike the end after the screwdriver holder is placed in the head of the screw and rotated in the desired direction. The force from the hammer blow does two things: It applies a force downward holding the tip of the screwdriver in the slot and then applies a twisting force to loosen (or tighten) the screw. SEE FIGURE 9–20.
FIGURE 9–21 A typical ball-peen hammer.
FIGURE 9–22 A rubber mallet used to deliver a force to an object without harming the surface.
FIGURE 9–23 A dead-blow hammer that was left outside in freezing weather. The plastic covering was damaged, which destroyed this hammer. The lead shot is encased in the metal housing and then covered.
SAFE USE OF SCREWDRIVERS. Always use the proper type and size screwdriver that matches the fastener. Try to avoid pressing down on a screwdriver because if it slips, the screwdriver tip could go into your hand, causing serious personal injury. All screwdrivers should be cleaned after use. Do not use a screwdriver as a pry bar; always use the correct tool for the job.
SLIP-JOINT
SMALLER
HAMMERS AND MALLETS HAMMERS Hammers and mallets are used to force objects together or apart. The shape of the back part of the hammer head (called the peen) usually determines the name. For example, a ball-peen hammer has a rounded end like a ball and it is used to straighten oil pans and valve covers, using the hammer head, and for shaping metal, using the ball peen. SEE FIGURE 9–21. NOTE: A claw hammer has a claw used to remove nails and is not used for automotive service. A hammer is usually sized by the weight of the head of the hammer and the length of the handle. For example, a commonly used ball-peen hammer has an 8 oz head with an 11 in. handle.
MALLETS
Mallets are a type of hammer with a large striking surface, which allows the technician to exert force over a larger area than a hammer, so as not to harm the part or component. Mallets are made from a variety of materials including rubber, plastic, or wood. SEE FIGURE 9–22. A shot-filled plastic hammer is called a dead-blow hammer. The small lead balls (shot) inside a plastic head prevent the hammer from bouncing off of the object when struck. SEE FIGURE 9–23. SAFE USE OF HAMMERS AND MALLETS. All mallets and hammers should be cleaned after use and not exposed to extreme temperatures. Never use a hammer or mallet that is damaged in any way and always use caution to avoid doing damage to the components and the surrounding area. Always follow the hammer manufacturer’s recommended procedures and practices.
LARGER
FIGURE 9–24 Typical slip-joint pliers, which are also common household pliers. The slip joint allows the jaws to be opened to two different settings.
PLIERS SLIP-JOINT PLIERS
Pliers are capable of holding, twisting, bending, and cutting objects and are an extremely useful classification of tools. The common household type of pliers is called the slip-joint pliers. There are two different positions where the junction of the handles meets to achieve a wide range of sizes of objects that can be gripped. SEE FIGURE 9–24.
MULTIGROOVE ADJUSTABLE PLIERS For gripping larger objects, a set of multigroove adjustable pliers is a commonly used tool of choice by many service technicians. Originally designed to remove the various size nuts holding rope seals used in water pumps, the name water pump pliers is also used. SEE FIGURE 9–25. LINESMAN’S PLIERS Linesman’s pliers are specifically designed for cutting, bending, and twisting wire. While commonly used by construction workers and electricians, linesman’s pliers are very useful tools for the service technician who deals with wiring. The center parts of the jaws are designed to grasp round objects such as pipe or tubing without slipping. SEE FIGURE 9–26. DIAGONAL PLIERS Diagonal pliers are designed for cutting only. The cutting jaws are set at an angle to make it easier to cut
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MULTI-GROOVES FOR JAW WIDTH ADJUSTMENT
FIGURE 9–28 Needle-nose pliers are used where there is limited access to a wire or pin that needs to be installed or removed.
FIGURE 9–25 Multigroove adjustable pliers are known by many names, including the trade name Channel Locks. FLAT GRIP
RELEASE LEVER
CUTS SOFT WIRE
PIPE GRIP
FIGURE 9–29 Locking pliers are best known by their trade name Vise-Grip®.
SIDE CUTTERS
TECH TIP JOINT CUTTERS
Brand Name Versus Proper Term
GRIPS SMALL OBJECTS
FIGURE 9–26 A linesman’s pliers are very useful because they can help perform many automotive service jobs.
Technicians often use slang or brand names of tools rather than the proper term. This results in some confusion for new technicians. Some examples are given in the following table. Brand Name
Proper Term
Slang Name
Crescent wrench Vise Grip Channel Locks
Adjustable wrench Locking pliers Water pump pliers or multigroove adjustable pliers Diagonal cutting pliers
Monkey wrench Pump pliers
Dikes or side cuts
TECH TIP CUTTING WIRES CLOSE TO TERMINALS
Use Chalk Often soft metal particles can become stuck in a file, especially when using it to file aluminum or other soft metals. Rub some chalk into the file before using it to prevent this from happening.
PULLING OUT AND SPREADING COTTER PIN
FIGURE 9–27 Diagonal-cut pliers are another common tool that has many names. wires. Diagonal pliers are also called side cuts or dikes. These pliers are constructed of hardened steel and they are used mostly for cutting wire. SEE FIGURE 9–27.
NEEDLE-NOSE PLIERS
Needle-nose pliers are designed to grip small objects or objects in tight locations. Needle-nose pliers have long, pointed jaws, which allow the tips to reach into narrow openings or groups of small objects. SEE FIGURE 9–28.
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Most needle-nose pliers have a wire cutter located at the base of the jaws near the pivot. There are several variations of needlenose pliers, including right angle jaws or slightly angled to allow access to certain cramped areas.
LOCKING PLIERS Locking pliers are adjustable pliers that can be locked to hold objects from moving. Most locking pliers also have wire cutters built into the jaws near the pivot point. Locking pliers come in a variety of styles and sizes and are commonly referred to by their trade name Vise-Grip®. The size is the length of the pliers, not how far the jaws open. SEE FIGURE 9–29. SAFE USE OF PLIERS. Pliers should not be used to remove any bolt or other fastener. Pliers should only be used when specified for use by the vehicle manufacturer.
INTERNAL SNAP RING
STRAIGHT CUT TIN SNIP
OFFSET RIGHT-HAND AVIATION SNIP
FIGURE 9–32 Tin snips are used to cut thin sheets of metal or carpet. EXTERNAL SNAP RING
FIGURE 9–30 Snap-ring pliers are also called lock-ring pliers and are designed to remove internal and external snap rings (lock rings).
TRIANGULAR
FIGURE 9–33 A utility knife uses replaceable blades and is used to cut carpet and other materials.
CUTTERS
HALF ROUND
SNIPS
ROUND
FLAT HANDLE
FIGURE 9–31 Files come in many different shapes and sizes. Never use a file without a handle.
Service technicians are often asked to fabricate sheet metal brackets or heat shields and need to use one or more types of cutters available. The simplest is called tin snips, which are designed to make straight cuts in a variety of materials, such as sheet steel, aluminum, or even fabric. A variation of the tin snips is called aviation tin snips. There are three designs of aviation snips including one designed to cut straight (called a straight cut aviation snip), one designed to cut left (called an offset left aviation snip), and one designed to cut right (called an offset right aviation snip). The handles are color coded for easy identification. These include yellow for straight, red for left, and green for right. SEE FIGURE 9–32.
SNAP-RING PLIERS
Snap-ring pliers are used to remove and install snap rings. Many snap-ring pliers are designed to be able to remove and install inward, as well as outward, expanding snap rings. Snap-ring pliers can be equipped with serrated-tipped jaws for grasping the opening in the snap ring, while others are equipped with points, which are inserted into the holes in the snap ring. SEE FIGURE 9–30.
FILES
Files are used to smooth metal and are constructed of hardened steel with diagonal rows of teeth. Files are available with a single row of teeth called a single-cut file, as well as two rows of teeth cut at an opposite angle called a double-cut file. Files are available in a variety of shapes and sizes from small flat files, halfround files, and triangular files. SEE FIGURE 9–31.
SAFE USE OF FILES. Always use a file with a handle. Because files only cut when moved forward, a handle must be attached to prevent possible personal injury. After making a forward strike, lift the file and return the file to the starting position; avoid dragging the file backward.
UTILITY KNIFE A utility knife uses a replaceable blade and is used to cut a variety of materials such as carpet, plastic, wood, and paper products, such as cardboard. SEE FIGURE 9–33. SAFE USE OF CUTTERS. Whenever using cutters, always wear eye protection or a face shield to guard against the possibility of metal pieces being ejected during the cut. Always follow recommended procedures.
PUNCHES AND CHISELS PUNCHES A punch is a small diameter steel rod that has a smaller diameter ground at one end. A punch is used to drive a pin out that is used to retain two components. Punches come in a variety of sizes, which are measured across the diameter of the machined end. Sizes include 1/16 in., 1/8 in., 3/16 in., and 1/4 in. SEE FIGURE 9–34.
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CHAMFER
MUSHROOM
RIGHT
WRONG
FIGURE 9–36 Use a grinder or a file to remove the mushroom material on the end of a punch or chisel. PIN
FIGURE 9–34 A punch used to drive pins from assembled components. This type of punch is also called a pin punch.
SERRATED CAM
FIGURE 9–35 Warning stamped in the side of a punch warning that goggles should be worn when using this tool. Always follow safety warnings.
FIGURE 9–37 A stud remover uses an offset serrated wheel to grasp the stud so it will be rotated when a ratchet or breaker bar is used to rotate the assembly.
CUTTER
CHISELS
FORCING SCREW
A chisel has a straight, sharp cutting end that is used for cutting off rivets or to separate two pieces of an assembly. The most common design of chisel used for automotive service work is called a cold chisel. SAFE USE OF PUNCHES AND CHISELS. Always wear eye protection when using a punch or a chisel because the hardened steel is brittle and parts of the punch could fly off and cause serious personal injury. See the warning stamped on the side of this automotive punch in FIGURE 9–35. Punches and chisels can also have the top rounded off, which is called “mushroomed.” This material must be ground off to help avoid the possibility that the overhanging material is loosened and becomes airborne during use. SEE FIGURE 9–36.
REMOVERS Removers are tools used to remove damaged fasteners. A remover tool is not normally needed during routine service unless the fastener is corroded or has been broken or damaged by a previous attempt to remove the bolt or nut. To help prevent the need for a remover tool, all rusted and corroded fasteners should be sprayed with penetrating oil. Penetrating oil is a low viscosity oil that is designed to flow in between the threads of a fastener or other small separation between two parts. Commonly used penetrating oils include WD-40®, Kroil®, and CRC 5-56. CAUTION: Do not use penetrating oil as a lubricating oil because it is volatile and will evaporate soon after usage leaving little lubricant behind for protection.
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SCREW HEAD
FIGURE 9–38 A nut splitter is used to split a nut that cannot be removed. After the nut has been split, a chisel is then used to remove the nut.
Removers are a classification of tool used to remove stuck or broken fasteners. Over time, rust and corrosion can cause the threads of the fastener to be attached to the nut or the casting making it very difficult to remove. There are several special tools that can be used to remove damaged fasteners. Which one to use depends on the type of damage.
DAMAGED HEADS If the bolt head or a nut becomes damaged or rounded, there are two special tools that can be used, including:
Stud remover. A stud removal tool grips the part of the stud above the surface and uses a cam or wedge to grip the stud as it is being rotated by a ratchet or breaker bar. SEE FIGURE 9–37.
Nut splitter. A nut splitter is used to remove the nut by splitting it from the bolt. A nut splitter is used by inserting the cutter against a flat of the nut and tightening the threaded bolt of the splitter. The nut will be split away from the bolt and can then be removed. SEE FIGURE 9–38.
REPLACEABLE BLADE
FIGURE 9–41 A typical hacksaw that is used to cut metal. If cutting sheet metal or thin objects, a blade with more teeth should be used.
TECH TIP The Wax Trick FIGURE 9–39 A set of bolt extractors, commonly called easy outs.
Many times rusted fasteners can be removed by using heat to expand the metal and break the rust bond between the fastener and the nut or casting. Many technicians heat the fastener using a torch and then apply paraffin wax or a candle to the heated fastener. SEE FIGURE 9–40. The wax will melt and as the part cools, will draw the liquid wax down between the threads. After allowing the part to cool, attempt to remove the fastener. It will often be removed without any trouble.
?
FREQUENTLY ASKED QUESTION
I Broke Off an Easy Out—Now What?
FIGURE 9–40 Removing plugs or bolts is easier if the plug is first heated to cherry red color, using a torch, and then applying wax. During cooling, the wax flows in between the threads, making it easier to remove.
CAUTION: Do not rotate the entire nut splitter or damage to the cutting wedge will occur.
BROKEN BOLTS, STUDS, OR SCREWS
Often, bolts, studs, or screws break even with, or below the surface, making stud removal tools impossible to use. Bolt extractors are commonly called easy outs. An easy out is constructed of hardened steel with flutes or edges ground into the side in an opposite direction of most threads. SEE FIGURE 9–39.
NOTE: Always select the largest extractor that can be used to help avoid the possibility of breaking the extractor while attempting to remove the bolt. A hole is drilled into the center of a broken bolt. Then, the extractor (easy out) is inserted into the hole and rotated counterclockwise using a wrench. As the extractor rotates, the grooves grip tighter into the wall of the hole drilled in the broken bolt. As a result, most extractors are capable of removing most broken bolts.
An extractor (easy out) is hardened steel and removing this and the broken bolt is now a job for a professional machine shop. The part, which could be as large as an engine block, needs to be removed from the vehicle and taken to a machine shop that is equipped to handle this type of job. One method involves using an electrical discharge machine (EDM). An EDM uses a high amperage electrical current to produce thousands of arcs between the electrode and the broken tool. The part is submerged in a non-conducting liquid and each tiny spark vaporizes a small piece of the broken tool.
HACKSAWS A hacksaw is used to cut metals, such as steel, aluminum, brass, or copper. The cutting blade of a hacksaw is replaceable and the sharpness and number of teeth can be varied to meet the needs of the job. Use 14 or 18 teeth per inch (tpi) for cutting plaster or soft metals, such as aluminum and copper. Use 24 or 32 teeth per inch for steel or pipe. Hacksaw blades should be installed with the teeth pointing away from the handle. This means that a hacksaw cuts while the blade is pushed in the forward direction, and then pressure should be released as the blade is pulled rearward before repeating the cutting operation. SEE FIGURE 9–41. SAFE USE OF HACKSAWS. Check that the hacksaw is equipped with the correct blade for the job and that the teeth are pointed away from the handle. When using a hacksaw, move the hacksaw slowly away from you, then lift slightly and return for another cut.
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TECH TIP Hide Those from the Boss An apprentice technician started working for a dealership and put his top tool box on a workbench. Another technician observed that, along with a complete set of good-quality tools, the box contained several adjustable wrenches. The more experienced technician said, “Hide those from the boss.” If any adjustable wrench is used on a bolt or nut, the movable jaw often moves or loosens and starts to round the head of the fastener. If the head of the bolt or nut becomes rounded, it becomes that much more difficult to remove.
BASIC HAND TOOL LIST Hand tools are used to turn fasteners (bolts, nuts, and screws). The following is a list of hand tools every automotive technician should possess. Specialty tools are not included. Safety glasses Tool chest 1/4 in. drive socket set (1/4 to 9/16 in. standard and deep sockets; 6 to 15 mm standard and deep sockets) 1/4 in. drive ratchet 1/4 in. drive 2 in. extension 1/4 in. drive 6 in. extension 1/4 in. drive handle 3/8 in. drive socket set (3/8 to 7/8 in. standard and deep sockets; 10 to 19 mm standard and deep sockets)
FIGURE 9–42 A typical beginning technician tool set that includes the basic tools to get started.
13 to 14 mm flare nut wrench 15 to 17 mm flare nut wrench 5/16 to 3/8 in. flare nut wrench 7/16 to 1/2 in. flare nut wrench 1/2 to 9/16 in. flare nut wrench Diagonal pliers Needle pliers Adjustable-jaw pliers Locking pliers Snap-ring pliers Stripping or crimping pliers Ball-peen hammer
3/8 in. drive Torx set (T40, T45, T50, and T55)
Rubber hammer
3/8 in. drive 13/16 in. plug socket
Dead-blow hammer
3/8 in. drive 5/8 in. plug socket
Five-piece standard screwdriver set
3/8 in. drive ratchet
Four-piece Phillips screwdriver set
3/8 in. drive 1 1/2 in. extension
#15 Torx screwdriver
3/8 in. drive 3 in. extension
#20 Torx screwdriver
3/8 in. drive 6 in. extension
File
3/8 in. drive 18 in. extension
Center punch
3/8 in. drive universal
Pin punches (assorted sizes)
1/2 in. drive socket set (1/2 to 1 in. standard and deep sockets; 9 to 19 mm standard and deep metric sockets)
Chisel
1/2 in. drive ratchet
Valve core tool
1/2 in. drive breaker bar
Filter wrench (large filters)
1/2 in. drive 5 in. extension
Filter wrench (smaller filters)
1/2 in. drive 10 in. extension
Test light
3/8 to 1/4 in. adapter
Feeler gauge
1/2 to 3/8 in. adapter
Scraper
3/8 to 1/2 in. adapter
Magnet
Utility knife
Crowfoot set (fractional inch) Crowfoot set (metric) 3/8 through 1 in. combination wrench set
TOOL SETS AND ACCESSORIES
10 through 19 mm combination wrench set 1/16 through 1/4 in. hex (Allen) wrench set 2 through 12 mm hex (Allen) wrench set 3/8 in. hex socket
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A beginning service technician may wish to start with a small set of tools before spending a lot of money on an expensive, extensive tool box. SEE FIGURES 9–42 AND 9–43.
FIGURE 9–43 A typical large tool box, showing just one of many drawers.
FIGURE 9–44 A seal puller being used to remove a seal from a rear axle.
HAMMER
TECH TIP Need to Borrow a Tool More than Twice? Buy It! Most service technicians agree that it is okay for a beginning technician to borrow a tool occasionally. However, if a tool has to be borrowed more than twice, then be sure to purchase it as soon as possible. Also, whenever a tool is borrowed, be sure that you clean the tool and let the technician you borrowed the tool from know that you are returning the tool. These actions will help in any future dealings with other technicians.
CALIPER BODY
TECH TIP The Valve Grinding Compound Trick Apply a small amount of valve grinding compound to a Phillips or Torx screw or bolt head. The gritty valve grinding compound “grips” the screwdriver or tool bit and prevents the tool from slipping up and out of the screw head. Valve grinding compound is available in a tube from most automotive parts stores.
BOOT DRIVER
FIGURE 9–45 A seal driver or installer is usually plastic and is designed to seat the seal.
ELECTRICAL HAND TOOLS SEAL PULLERS AND DRIVERS SEAL PULLERS
Grease seals are located on many automotive components, including brake rotors, transmission housings, and differentials. A seal puller is used to properly remove grease seals, as shown in FIGURE 9–44.
SEAL DRIVERS
A seal driver can be either plastic or metal, usually aluminum, and is used to seat the outer lip of a grease seal into the grease seal pocket. A seal is usually driven into position using a plastic mallet and a seal driver that is the same size as the outside diameter of the grease seal retainer. SEE FIGURE 9–45.
TEST LIGHTS
A test light is used to test for electricity. A typical automotive test light consists of a clear plastic screwdriver-like handle that contains a light bulb. A wire is attached to one terminal of the bulb, which the technician connects to a clean metal part of the vehicle. The other end of the bulb is attached to a point that can be used to test for electricity at a connector or wire. When there is power at the point and a good connection at the other end, the light bulb lights. SEE FIGURE 9–46.
SOLDERING GUNS
Electric soldering gun. This type of soldering gun is usually powered by 110 volt AC and often has two power settings expressed in watts. A typical electric soldering gun will
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BUTANE-POWERED
ELECTRIC
FIGURE 9–46 A typical 12 volt test light. produce from 85 to 300 watts of heat at the tip, which is more than adequate for soldering. SEE FIGURE 9–47.
Electric soldering pencil. This type of soldering iron is less expensive and creates less heat than an electric soldering gun. A typical electric soldering pencil (iron) creates 30 to 60 watts of heat and is suitable for soldering smaller wires and connections.
Butane-powered soldering iron. A butane-powered soldering iron is portable and very useful for automotive service work because an electrical cord is not needed. Most butanepowered soldering irons produce about 60 watts of heat, which is enough for most automotive soldering.
FIGURE 9–47 An electric soldering gun used to make electrical repairs. Soldering guns are sold by the wattage rating. The higher the wattage, the greater amount of heat created. Most solder guns used for automotive electrical work usually fall within the 60 to 160 watt range.
TECH TIP It Just Takes a Second Whenever removing any automotive component, it is wise to screw the bolts back into the holes a couple of threads by hand. This ensures that the right bolt will be used in its original location when the component or part is put back on the vehicle. Often, the same diameter of fastener is used on a component, but the length of the bolt may vary. Spending just a couple of seconds to put the bolts and nuts back where they belong when the part is removed can save a lot of time when the part is being reinstalled. Besides making certain that the right fastener is being installed in the right place, this method helps prevent bolts and nuts from getting lost or kicked away. How much time have you wasted looking for that lost bolt or nut?
In addition to a soldering iron, most service technicians who do electrical-related work should have the following:
Wire cutters
Wire strippers
Wire crimpers
Heat gun
A digital meter is a necessary tool for any electrical diagnosis and troubleshooting. A digital multimeter, abbreviated DMM, is usually capable of measuring the following units of electricity.
DC volts
AC volts
Ohms
Amperes
SAFETY TIPS FOR USING HAND TOOLS
fastener. (If heat is used on a bolt or nut to remove it, always replace it with a new part.)
Always use the proper tool for the job. If a specialized tool is required, use the proper tool and do not try to use another tool improperly.
Never expose any tool to excessive heat. High temperatures can reduce the strength (“draw the temper”) of metal tools.
Never use a hammer on any wrench or socket handle unless you are using a special “staking face” wrench designed to be used with a hammer.
Replace any tools that are damaged or worn.
The following safety tips should be kept in mind whenever you are working with hand tools.
Always pull a wrench toward you for best control and safety. Never push a wrench.
Keep wrenches and all hand tools clean to help prevent rust and to allow for a better, firmer grip.
Always use a 6-point socket or a box-end wrench to break loose a tight bolt or nut.
Use a box-end wrench for torque and an open-end wrench for speed.
Never use a pipe extension or other type of “cheater bar” on a wrench or ratchet handle. If more force is required, use a larger tool or use penetrating oil and/or heat on the frozen
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HAND TOOL MAINTENANCE Most hand tools are constructed of rust-resistant metals but they can still rust or corrode if not properly maintained. For best results and long tool life, the following steps should be taken.
Clean each tool before placing it back into the tool box.
Keep tools separated. Moisture on metal tools will start to rust more readily if the tools are in contact with another metal tool.
TECH TIP Use a Binder Clip A binder clip (size 1 1/4 in. wide) is used by wise technicians to help keep fender covers in place. SEE FIGURE 9–48. Binder clips are found at office supply stores.
Line the drawers of the tool box with a material that will prevent the tools from moving as the drawers are opened and closed. This helps to quickly locate the proper tool and size.
Release the tension on all “clicker-type” torque wrenches after use.
Keep the tool box secure.
FIGURE 9–48 A binder clip being used to keep a fender cover from falling.
REVIEW QUESTIONS 1. Why are wrenches offset 15 degrees?
4. Which type of screwdriver requires the use of a hammer or mallet?
2. What are the other names for a line wrench?
5. What is inside a dead-blow hammer?
3. What are the standard automotive drive sizes for sockets?
6. What type of cutter is available in left and right cutters?
CHAPTER QUIZ 1. When working with hand tools, always ______________. a. Push the wrench—don’t pull toward you b. Pull a wrench—don’t push a wrench 2. The proper term for Channel Locks is ______________. a. Vise Grips b. Crescent wrench c. Locking pliers d. Multigroove adjustable pliers 3. The proper term for Vise Grips is ______________. a. Locking pliers c. Side cuts b. Slip-joint pliers d. Multigroove adjustable pliers 4. Which tool listed is a brand name? a. Locking pliers c. Side cutters b. Monkey wrench d. Vise Grips 5. Two technicians are discussing torque wrenches. Technician A says that a torque wrench is capable of tightening a fastener with more torque than a conventional breaker bar or ratchet. Technician B says that a torque wrench should be calibrated regularly for the most accurate results. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
6. What type of screwdriver should be used if there is very limited space above the head of the fastener? a. Offset screwdriver b. Stubby screwdriver c. Impact screwdriver d. Robertson screwdriver 7. Where is the “peen” of the hammer? a. The striking face b. The handle c. The back part opposite the striking face d. The part that connects to the handle 8. What type of hammer is plastic coated, has a metal casing inside, and is filled with small lead balls? a. Dead-blow hammer b. Soft-blow hammer c. Sledge hammer d. Plastic hammer 9. Which type of pliers is capable of fitting over a large object? a. Slip-joint pliers c. Locking pliers b. Linesman’s pliers d. Multigroove adjustable pliers 10. Which tool has a replaceable cutting edge? a. Side-cut pliers c. Utility knife b. Tin snips d. Aviation snips
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10
POWER TOOLS AND SHOP EQUIPMENT
OBJECTIVES: After studying Chapter 10, the reader should be able to: • Identify commonly used power tools. • Identify commonly used shop equipment. • Discuss the proper use of power tools and shop equipment. • Describe the safety procedures that should be followed when working with power tools and shop equipment. KEY TERMS: Air-blow gun 84 • Air compressor 82 • Air drill 84 • Air ratchet 83 • Bearing splitter 85 • Bench grinder 85 • Bench vise 85 • Die grinder 84 • Engine stand 86 • Hydraulic press 85 • Impact wrench 82 • Incandescent light 84 • Light-emitting diode (LED) 84 • Portable crane 85 • Stone wheel 84 • Trouble light 84 • Wire brush wheel 84 • Work light 84
AIR COMPRESSOR A shop air compressor is usually located in a separate room or an area away from the customer area of a shop. An air compressor is powered by a 220 V AC electric motor and includes a storage tank and the compressor itself, as well as the pressure switches, which are used to maintain a certain minimum level of air pressure in the system. The larger the storage tank, expressed in gallons, the longer an air tool can be operated in the shop without having the compressor start operating. SEE FIGURE 10–1.
SAFE USE OF COMPRESSED AIR
Air under pressure can create dangerous situations. For example, an object, such as a small piece of dirt, could be forced out of an air hose blow gun with enough force to cause serious personal injury. All OSHA-approved air nozzles have air vents drilled around the outside of the main discharge hole to help reduce the force of the air blast. Also, the air pressure used by an air nozzle (blow gun) must be kept to 30 PSI (207 kPa) or less. SEE FIGURE 10–2.
AIR AND ELECTRICALLY OPERATED TOOLS IMPACT WRENCH
An impact wrench, either air (pneumatic) or electrically powered, is a tool that is used to remove and install fasteners. The air-operated 1/2 in. drive impact wrench is the most commonly used unit. SEE FIGURE 10–3. The direction of rotation is controlled by a switch. SEE FIGURE 10–4. Electrically powered impact wrenches commonly include:
Battery-powered units. SEE FIGURE 10–5. 110-volt AC-powered units. This type of impact wrench is very useful, especially if compressed air is not readily available.
CAUTION: Always use impact sockets with impact wrenches, and be sure to wear eye protection in case the socket or fastener shatters. Impact sockets are thicker walled and constructed with premium alloy steel. They are hardened with a black oxide finish to help prevent corrosion and distinguish them from regular sockets. SEE FIGURE 10–6. AIR NOZZLE TRIGGER DISCHARGE TIP NOZZLE
SIDE VENT OPENING
FIGURE 10–1 A typical shop compressor. It is usually placed out of the way, yet accessible to provide for maintenance to the unit.
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AIR HOSE CONNECTOR
FIGURE 10–2 Always use an air nozzle that is OSHA approved. The openings in the side are used to allow air to escape if the nozzle tip were to become clogged.
FIGURE 10–3 A typical 1/2 in. drive impact wrench. FIGURE 10–5 A typical battery-powered 3/8 in. drive impact wrench.
FIGURE 10–4 This impact wrench features a variable torque setting using a rotary knob. The direction of rotation can be changed by pressing the button at the bottom.
FIGURE 10–6 A black impact socket. Always use impact-type sockets whenever using an impact wrench to avoid the possibility of shattering the socket, which can cause personal injury.
REAL WORLD FIX The Case of the Rusty Air Impact Wrenches In one busy shop, it was noticed by several technicians that water was being pumped through the air compressor lines and out of the vents of air impact wrenches whenever they were used. It is normal for moisture in the air to condense in the air storage tank of an air compressor. One of the routine service procedures is to drain the water from the air compressor. The water had been drained regularly from the air compressor at the rear of the shop, but the problem continued. Then someone remembered that there was a second air compressor mounted over the parts department. No one could remember ever draining the tank from that compressor. After that tank was drained, the problem of water in the lines was solved. The service manager assigned a person to drain the water from both compressors every day and to check the oil level. The oil in the compressor is changed every six months to help ensure long life of the expensive compressors.
FIGURE 10–7 An air ratchet is a very useful tool that allows fast removal and installation of fasteners, especially in areas that are difficult to reach or do not have room enough to move a hand ratchet wrench.
AIR RATCHET
An air ratchet is used to remove and install fasteners that would normally be removed or installed using a ratchet and a socket. An air ratchet is much faster, yet has an air hose attached, which reduces accessibility to certain places. SEE FIGURE 10–7.
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FIGURE 10–8 This typical die grinder surface preparation kit includes the air-operated die grinder, as well as a variety of sanding discs for smoothing surfaces or removing rust.
FIGURE 10–9 A fluorescent trouble light operates cooler and is safer to use in the shop because it is protected against accidental breakage where gasoline or other flammable liquids would happen to come in contact with the light.
WARNING
DIE GRINDER
A die grinder is a commonly used air-powered tool, which can also be used to sand or remove gaskets and rust. SEE FIGURE 10–8.
Do not use incandescent trouble lights around gasoline or other flammable liquids. The liquids can cause the bulb to break and the hot filament can ignite the flammable liquid.
AIR DRILL
An air drill is a drill that rotates faster than electric drills (up to 20,000 RPM). Air drills are commonly used in auto body work when many holes need to be drilled for plug welding.
AIR-BLOW GUN
An air-blow gun is used to clean equipment and other purposes where a stream of air would be needed. Automotive air-blow guns should meet OSHA requirements and include passages to allow air to escape outward at the nozzle, thereby relieving pressure if the nozzle were to become blocked.
AIR-OPERATED GREASE GUN An air-operated grease gun uses shop air to operate a plunger, which then applies a force to the grease cartridge. Most air-operated grease guns use a 1/4 in. air inlet and operate on 90 PSI of air pressure. BATTERY-POWERED GREASE GUN Battery-powered grease guns are more expensive than air-operated grease guns but offer the convenience of not having an air hose attached, making use easier. Many use rechargeable 14 to 18 volt batteries and use standard grease cartridges.
FLUORESCENT A trouble light is an essential piece of shop equipment, and for safety, should be fluorescent rather than incandescent. Incandescent light bulbs can scatter or break if gasoline were to be splashed onto the bulb creating a serious fire hazard. Fluorescent light tubes are not as likely to be broken and are usually protected by a clear plastic enclosure. Trouble lights are usually attached to a retractor, which can hold 20 to 50 ft of electrical cord. SEE FIGURE 10–9. LED TROUBLE LIGHT
Light-emitting diode (LED) trouble lights are excellent to use because they are shock resistant, long lasting, and do not represent a fire hazard. Some trouble lights are battery powered and therefore can be used in places where an attached electrical cord could present problems.
BENCH/PEDESTAL GRINDER A grinder can be mounted on a workbench or on a stand-alone pedestal.
TROUBLE LIGHTS INCANDESCENT
Incandescent lights use a filament that produces light when electric current flows through the bulb. This was the standard trouble light, also called a work light, for many years until safety issues caused most shops to switch to safer fluorescent or LED lights. If incandescent light bulbs are used, try to locate bulbs that are rated “rough service,” which is designed to withstand shock and vibration more than conventional light bulbs.
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BENCH- OR PEDESTAL-MOUNTED GRINDER These high-powered grinders can be equipped with a wire brush wheel and/or a stone wheel.
A wire brush wheel is used to clean steel or sheet metal parts.
A stone wheel is used to grind metal or to remove the mushroom from the top of punches or chisels. SEE FIGURE 10–10.
CAUTION: Always wear a face shield when using a wire wheel or a grinder. Also keep the part support ledge (table), also called a throat plate, within 1/16 inch (2 mm) of the stone.
FIGURE 10–10 A typical pedestal grinder with a wire wheel on the left side and a stone wheel on the right side. Even though this machine is equipped with guards, safety glasses or a face shield should always be worn when using a grinder or wire wheel.
FIGURE 10–12 A hydraulic press is usually used to press bearings on and off on rear axles and transmissions. most vises are serrated and can cause damage to some components unless protected. Many types of protection can be used, including aluminum or copper jaw covers or by simply placing wood between the vise jaws and the component being held. SEE FIGURE 10–11. SAFE USE OF VISES. The jaws of vises can cause damage to the part or component being held. Use pieces of wood or other soft material between the steel jaws and the workpiece to help avoid causing damage. Many vises are sold with optional aluminum jaw covers. When finished using a vise, be sure to close the jaws and place the handle straight up and down to help avoid personal injury to anyone walking near the vise. FIGURE 10–11 A typical vise mounted to a workbench. Most bench grinders are equipped with a grinding wheel (stone) on one side and a wire brush wheel on the other side. A bench grinder is a very useful piece of shop equipment and the wire wheel end can be used for the following:
Cleaning threads of bolts
Cleaning gaskets from sheet metal parts, such as steel valve covers
CAUTION: Only use a steel wire brush on steel or iron components. If a steel wire brush is used on aluminum or copper-based metal parts, it can remove metal from the part. The grinding stone end of the bench grinder can be used for the following:
Sharpening blades and drill bits
Grinding off the heads of rivets or parts
Sharpening sheet metal parts for custom fitting
BENCH VISE A bench vise is used to hold components so that work can be performed on the unit. The size of a vise is determined by the width of the jaws. Two common sizes of vises are 4 in. and 6 in. models. The jaws of
HYDRAULIC PRESSES Hydraulic presses are hand-operated hydraulic cylinders mounted to a stand and designed to press bearings on or off of shafts, as well as other components. To press off a bearing, a unit called a bearing splitter is often required to apply force to the inner race of a bearing. Hydraulic presses use a pressure gauge to show the pressure being applied. Always follow the operating instructions supplied by the manufacturer of the hydraulic press. SEE FIGURE 10–12.
PORTABLE CRANE AND CHAIN HOIST A portable crane is used to remove and install engines and other heavy vehicle components. Most portable cranes use a handoperated hydraulic cylinder to raise and lower a boom that is equipped with a nylon strap or steel chain. At the end of the strap or chain is a steel hook that is used to attach around a bracket or auxiliary lifting device. SEE FIGURE 10–13. SAFE USE OF PORTABLE CRANES. Always be sure to attach the hook(s) of the portable crane to a secure location on the unit being
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FIGURE 10–13 A typical portable crane used to lift and move heavy assemblies, such as engines and transmissions. TECH TIP
FIGURE 10–14 Two engines on engine stands. The plastic bags over the engines help keep dirt from getting onto these engines and engine parts.
Cover Work While Pressing Whenever pressing on a bearing or other component, use an old brake drum over the shaft and the bearing. In the event the bearing shatters during the pressing operation, the brake drum will prevent the parts of the bearing from flying outward where they could cause serious personal injury.
lifted. The hook should also be attached to the center of the weight of the object so it can be lifted straight up without tilting. CAUTION: Always keep feet and other body parts out from underneath the engine or unit being lifted. Always work around a portable crane as if the chain or strap could break at any time.
ENGINE STANDS An engine stand is designed to safely hold an engine and to allow it to be rotated. This allows the technician to easily remove, install, and perform service work to the engine. SEE FIGURE 10–14. Most engine stands are constructed of steel and supported by four casters to allow easy movement. There are two basic places where an engine stand attaches to the engine depending on the size of the engine. For most engines and stands, the retaining bolts attach to the same location as the bell housing at the rear of the engine. On larger engines, such as the 5.9 Cummins inline 6-cylinder diesel engine, the engine mounts to the stand using the engine mounting holes in the block. SEE FIGURE 10–15. SAFE OPERATION OF AN ENGINE STAND. When mounting an engine to an engine stand, be sure that the engine is being supported by a portable crane. Be sure the attaching bolts are grade 5 or 8 and the same thread size as the threaded holes in the block. Check that there is at least 1/2 inch (13 mm) of bolt thread engaged in the threaded holes in the engine block. Be sure that all attaching bolts are securely tightened before releasing the weight of the engine from the crane. Use caution when loosening the rotation retaining bolts because the engine could rotate rapidly, causing personal injury.
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FIGURE 10–15 An engine stand that grasps the engine from the sides rather than the end.
CARE AND MAINTENANCE OF SHOP EQUIPMENT All shop equipment should be maintained in safe working order. Maintenance of shop equipment usually includes the following operations or procedures.
Keep equipment clean. Dirt and grime can attract and hold moisture, which can lead to rust and corrosion. Oil or grease can attract dirt.
Keep equipment lubricated. While many bearings are sealed and do not require lubrication, always check the instructions for the use of the equipment for suggested lubrication and other service procedures.
CAUTION: Always follow the instructions from the equipment manufacturer regarding proper use and care of the equipment.
SETUP AND LIGHTING A TORCH
1
Inspect the cart and make sure the tanks are chained properly before moving it to the work location.
2
Start by attaching the appropriate work tip to the torch handle. The fitting should only be tightened hand tight. Make sure the valves on the torch handle are closed at this time.
3
Each tank has a regulator assembly with two gauges. The high pressure gauge shows tank pressure, and the low pressure gauge indicates working pressure.
4
Open the oxygen tank valve fully, and open the acetylene tank valve 1/2 turn.
5
Open the oxygen valve on the torch handle 1/4 turn in preparation for adjusting oxygen gas pressure.
6
Turn the oxygen regulator valve clockwise and adjust oxygen gas pressure to 20 PSI. Close the oxygen valve on the torch handle.
CONTINUED
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SETUP AND LIGHTING A TORCH
7
Open the acetylene valve on the torch handle 1/4 turn and adjust acetylene gas pressure to 7 PSI. Close the acetylene valve on the torch handle.
8
9
Put on leather gloves and open the acetylene valve on the torch handle 1/4 turn. Use a flint striker to ignite the acetylene gas exiting the torch tip.
10
Adjust the acetylene valve until the base of the flame just touches the torch tip. Slowly open the oxygen valve on the torch handle and adjust for a neutral flame (blue cone is well-defined).
12
Close the valves on both tanks and turn the regulator handles CCW until they no longer contact the internal springs. Open the gas valves briefly on the torch handle to release gas pressure from the hoses. Close the gas valves on the torch handle and put away the torch assembly.
11
Once work is complete, extinguish the flame by quickly closing the acetylene valve on the torch handle. Be prepared to hear a loud “pop” when the flame goes out. Close the oxygen valve on the torch handle.
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Open the oxygen valve on the torch handle 1/4 turn and use an appropriate size tip cleaner to clean the tip orifice. Finish by closing the oxygen valve.
HEATING METAL
1
Heating attachments include ordinary heating tips, middle and right and a “rosebud” (left). Ordinary heating tips work fine for most purposes, but occasionally the rosebud is utilized when a great deal of heat is needed.
3
Any time heating or cutting operations are being performed, be sure that any flammables have been removed from the immediate area. A fire blanket may be placed over floor drains or other objects to prevent fires. A fire extinguisher should be on hand in case of an emergency.
5
Note that heating operations should be performed over steel or firebrick. Never heat or cut steel close to concrete, as it could cause the concrete to explode.
2
Note that while acetylene tank pressures are relatively low, the oxygen tank can be filled to over 2,000 PSI. This can represent a serious hazard if precautions are not taken. Be absolutely certain that the tanks are chained properly to the cart before attempting to move it!
4
Be sure to wear appropriate personal protective equipment during heating and cutting operations.
6
When heating steel, move the torch in a circular pattern to prevent melting of the metal. Don’t hold the torch too close to the work as this will cause a “snapping” or “backfire” that can extinguish the flame. CONTINUED
PO W E R T O O L S AN D SH OP EQU IP M EN T
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CUTTING METAL
7
Affix the cutting attachment to the torch handle. Note that the cutting attachment has a cutting handle and a separate oxygen valve.
9
Oxygen gas pressure should be adjusted to 30 PSI whenever using the cutting attachment. Acetylene pressure is kept at 7 PSI.
11 90
Direct the flame onto a thin spot or sharp edge of the metal to be cut. This will build the heat quicker in order to get the cut started.
CHAPTER 1 0
8
Fully open the oxygen valve on the torch handle. Oxygen flow will now be controlled with the valve on the cutting attachment.
10
Open the acetylene valve on the torch handle 1/4 turn and light the torch. Adjust the flame until its base just touches the cutting tip. Slowly open the oxygen valve on the cutting attachment and adjust the flame until the blue cone is well-defined.
12
When the metal glows red, depress the cutting handle and move the torch to advance the cut. You will need to move the torch faster when cutting thinner pieces of steel. On thicker pieces, point the cutting tip into the direction of the cut.
REVIEW QUESTIONS 1. List the tools used by service technicians that use compressed air.
3. What safety precautions should be adhered to when working with a vise?
2. Which trouble light design(s) is (are) the recommended type for maximum safety?
4. When using a blow gun, what precautions need to be taken?
CHAPTER QUIZ 1. When using compressed air and a blow gun, what is the maximum allowable air pressure? a. 10 PSI c. 30 PSI b. 20 PSI d. 40 PSI 2. Which air impact drive size is the most commonly used? a. 1/4 in. c. 1/2 in. b. 3/8 in. d. 3/4 in. 3. What type of socket should be used with an air impact wrench? a. Black c. 12 point b. Chrome d. Either a or b 4. What can be used to cover the jaws of a vise to help protect the object being held? a. Aluminum c. Copper b. Wood d. All of the above 5. Technician A says that impact sockets have thicker walls than conventional sockets. Technician B says that impact sockets have a black oxide finish. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
chapter
11
6. Two technicians are discussing the use of a typical bench/ pedestal-mounted grinder. Technician A says that a wire brush wheel can be used to clean threads. Technician B says that the grinding stone can be used to clean threads. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 7. A hydraulic press is being used to separate a bearing from a shaft. What should be used to cover the bearing during the pressing operation? a. Shop cloth c. Fender cover b. Brake drum d. Paper towel 8. Which type of trouble light is recommended for use in the shop? a. Incandescent c. LED b. Fluorescent d. Either b or c 9. When mounting an engine to an engine stand, what grade of bolt should be used? a. 5 or 8 c. 3 or 5 b. 4 or 7 d. 1 or 4 10. Proper care of shop equipment includes ______________. a. Tuning up every six months b. Keeping equipment clean c. Keeping equipment lubricated d. Both b and c
VEHICLE LIFTING AND HOISTING
OBJECTIVES: After studying Chapter 11, the reader should be able to: • Identify vehicle hoisting and lifting equipment. • Discuss safety procedures related to hoisting or lifting a vehicle. • Describe the proper methods to follow to safely hoist a vehicle. KEY TERMS: Creeper 92 • Floor jack 91 • Jack stands 91 • Safety stands 91
FLOOR JACK A floor jack is a hand-operated hydraulic device that is used to lift vehicles or components, such as engines, transmissions, and rear axle assemblies. Most floor jacks use four casters, which allow the jack to be easily moved around the shop. SEE FIGURE 11–1.
SAFE USE OF FLOOR JACKS. Floor jacks are used to lift a vehicle or major vehicle component, but they are not designed to hold a load. Therefore safety stands, also called jack stands should always be used to support the vehicle. After the floor jack has lifted the vehicle, safety stands should be placed under the vehicle, and then, using the floor jack, lowered onto the safety stands. The floor jack can be lifted in position as another safety device but the load should be removed from the floor jack. If a load is retained on the floor jack,
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RAISE VEHICLE
LIFT POINT LOCATION SYMBOL
HANDLE
OPEN RELEASE VALVE (LOWER JACK) SADDLE LIFTING ARM CLOSE RELEASE VALVE
RELEASE VALVE
FRONT WHEELS REAR CASTER
FIGURE 11–1 A hydraulic hand-operated floor jack.
FIGURE 11–3 Most newer vehicles have a triangle symbol indicating the recommended hoisting lift points. which lifts the vehicle using hydraulic cylinders. Hoists are rated by the maximum weight that they can safely lift, such as 7,000 to 12,000 or more. Hoists can also have equal length arms or can be equipped with different length arms allowing the vehicle to be set so the doors can be opened and not hit the center support column. Many chassis and underbody service procedures require that the vehicle be hoisted or lifted off the ground. The simplest methods involve the use of drive-on ramps or a floor jack and safety (jack) stands, whereas in ground or surface-mounted lifts provide greater access.
SETTING THE PADS IS A CRITICAL PART OF THIS PROCEDURE All automobile and light-truck service manuals in-
FIGURE 11–2 Safety stands are being used to support the rear of this vehicle. Notice a creeper also. hydraulic fluid can leak past seals in the hydraulic cylinders, which would lower the vehicle, possibly causing personal injury. SEE FIGURE 11–2.
clude recommended locations to be used when hoisting (lifting) a vehicle. Some vehicles have a decal on the driver’s door indicating the recommended lift points. The recommended standards for the lift points and lifting procedures are found in SAE Standard JRP2184. SEE FIGURE 11–3. These recommendations typically include the following points. 1. The vehicle should be centered on the lift or hoist so as not to overload one side or put too much force either forward or rearward. Use tall safety stands if a major component is going to be removed from the vehicle, such as the engine, to help support the vehicle. SEE FIGURE 11–4. 2. The pads of the lift should be spread as far apart as possible to provide a stable platform.
CREEPERS When working underneath a vehicle, most service technicians use a creeper, which consists of a flat or concaved surface equipped with low-profile casters. A creeper allows the technician to maneuver under the vehicle easily.
SAFE USE OF CREEPERS
Creepers can create a fall hazard if left on the floor. When a creeper is not being used, it should be picked up and placed vertically against a wall or tool box to help prevent accidental falls.
VEHICLE HOISTS Vehicle hoists include older in-ground pneumatic/hydraulic (air pressure over hydraulic) and above-ground units. Most of the vehicle hoists used today use an electric motor to pressurize hydraulic fluid,
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CHAPTER 1 1
3. Each pad should be placed under a portion of the vehicle that is strong and capable of supporting the weight of the vehicle. a. Pinch welds at the bottom edge of the body are generally considered to be strong. CAUTION: Even though pinch weld seams are the recommended location for hoisting many vehicles with unitized bodies (unit-body), care should be taken not to place the pad(s) too far forward or rearward. Incorrect placement of the vehicle on the lift could cause the vehicle to be imbalanced, and the vehicle could fall. This is exactly what happened to the vehicle in FIGURE 11–5. b. Boxed areas of the body are the best places to position the pads on a vehicle without a frame. Be careful to note whether the arms of the lift might come into contact with other parts of the vehicle before the pad touches the intended location. Commonly damaged areas include the following: (1) Rocker panel moldings (2) Exhaust system (including catalytic converter) (3) Tires or body panels. SEE FIGURES 11–6 AND 11–7.
FIGURE 11–5 This training vehicle fell from the hoist when the pads were not set correctly. No one was hurt, but the vehicle was damaged.
(a)
(a)
(b)
FIGURE 11–4 (a) Tall safety stands can be used to provide additional support for a vehicle while on a hoist. (b) A block of wood should be used to avoid the possibility of doing damage to components supported by the stand.
4. As soon as the pads touch the vehicle, check for proper pad placement. The vehicle should be raised about 1 ft (30 cm) off the floor, then stopped and shaken to check for stability. If the vehicle seems to be stable when checked at a short distance from the floor, continue raising the vehicle and continue to view the vehicle until it has reached the desired height. The hoist should be lowered onto the mechanical locks, and then raised off of the locks before lowering. CAUTION: Do not look away from the vehicle while it is being raised (or lowered) on a hoist. Often one side or one end of the hoist can stop or fail, resulting in the vehicle being slanted enough to slip or fall.
(b)
FIGURE 11–6 (a) An assortment of hoist pad adapters that are often necessary to safely hoist many pickup trucks, vans, and sport utility vehicles. (b) A view from underneath a Chevrolet pickup truck showing how the pad extensions are used to attach the hoist lifting pad to contact the frame.
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CHOCK DRIVE-ON RAMPS (a)
FIGURE 11–8 Drive-on-type ramps. The wheels on the ground level must be chocked (blocked) to prevent accidental movement down the ramp.
5. Before lowering the hoist, the safety latch(es) must be released and the direction of the controls reversed. The speed downward is often adjusted to be as slow as possible for additional safety.
DRIVE-ON RAMPS (b)
FIGURE 11–7 (a) In this photo the pad arm is just contacting the rocker panel of the vehicle. (b) This photo shows what can occur if the technician places the pad too far inward underneath the vehicle. The arm of the hoist has dented in the rocket panel.
HINT: Most hoists can be safely placed at any desired height as long as it is high enough for the safety latches to engage. For ease while working, the area in which you are working should be at chest level. When working on brakes or suspension components, it is not necessary to work on them down near the floor or over your head. Raise the hoist so that the components are at chest level.
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Ramps are an inexpensive way to raise the front or rear of a vehicle. SEE FIGURE 11–8. Ramps are easy to store, but they can be dangerous because they can “kick out” when driving the vehicle onto the ramps. CAUTION: Professional repair shops do not use ramps because they are dangerous to use. Use only with extreme care.
HOISTING THE VEHICLE
1
The first step in hoisting a vehicle is to properly align the vehicle in the center of the stall.
2
Most vehicles will be correctly positioned when the left front tire is centered on the tire pad.
3
The arms can be moved in and out and most pads can be rotated to allow for many different types of vehicle construction.
4
Most lifts are equipped with short pad extensions that are often necessary to use to allow the pad to contact the frame of a vehicle without causing the arm of the lift to hit and damage parts of the body.
5
Tall pad extensions can also be used to gain access to the frame of a vehicle. This position is needed to safely hoist many pickup trucks, vans, and sport utility vehicles.
6
An additional extension may be necessary to hoist a truck or van equipped with running boards to give the necessary clearance.
CONTINUED
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HOISTING THE VEHICLE
(CONTINUED)
7
Position the pads under the vehicle under the recommended locations.
9
With the vehicle raised one foot (30 cm) off the ground, push down on the vehicle to check to see if it is stable on the pads. If the vehicle rocks, lower the vehicle and reset the pads. The vehicle can be raised to any desired working level. Be sure the safety is engaged before working on or under the vehicle.
11
When the service work is completed, the hoist should be raised slightly and the safety released before using the hydraulic to lower the vehicle.
96
CHAPTER 1 1
8
After being sure all pads are correctly positioned, use the electromechanical controls to raise the vehicle.
10
If raising a vehicle without a frame, place the flat pads under the pinch weld seam to spread the load. If additional clearance is necessary, the pads can be raised as shown.
12
After lowering the vehicle, be sure all arms of the lift are moved out of the way before driving the vehicle out of the work stall.
REVIEW QUESTIONS 1. Why must safety stands be used after lifting a vehicle with a floor jack?
3. What precautions should be adhered to when hoisting a vehicle?
2. What precautions should be adhered to when storing a creeper?
CHAPTER QUIZ 1. A safety stand is also called a ______________. a. Jack c. Bottle jack b. Jack stand d. Safety stool 2. A creeper should be stored ______________. a. Vertically c. Flat on the floor b. Under a vehicle d. Upside down on the floor 3. The SAE standard for hoist location is ______________. a. J-1980 c. JRP-2184 b. SAE-2009 d. J-14302 4. Tall safety stands would be used to ______________. a. Help support the vehicle when a major component is removed from the vehicle. b. Lift a vehicle c. Lift a component such as an engine high off the ground d. Both b and c 5. Commonly damaged areas of a vehicle during hoisting include ______________. a. Rocker panels c. Tires or body panels b. Exhaust systems d. All of the above 6. Pad extensions may be needed when hoisting what type of vehicle? a. Small cars c. Vans b. Pickup trucks d. Either b or c
chapter
12
7. Technician A says that a hoist can be stopped at any level as long as the safety latch engages. Technician B says that the vehicle should be hoisted to the top of the hoist travel for safety. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 8. Before lowering the vehicle, what should the technician do? a. Be sure nothing is underneath the vehicle b. Raise the vehicle enough to release the safety latch c. Be sure no one will be walking under or near the vehicle d. All of the above 9. Technician A says that a creeper should be stored vertically. Technician B says that a creeper should be stored on its casters. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 10. When checking for stability, how high should the vehicle be raised? a. About 2 in. (5 cm) c. About 1 ft (30 cm) b. About 6 in. (15 cm) d. About 3 ft (91 cm)
MEASURING SYSTEMS AND TOOLS
OBJECTIVES: After studying Chapter 12, the reader should be able to: • Describe how to read a ruler. • Explain how to use a micrometer and vernier dial caliper. • Describe how to use a telescopic gauge and a micrometer to measure cylinder and lifter bores. • Discuss how to measure valve guides using a small-hole gauge. • Explain how to use feeler gauges and dial indicators. KEY TERMS: Feeler gauge 102 • Sleeve 99 • Small-hole gauge 100 • Spindle 99 • Split-ball gauge 100 • Straightedge 103 • Thickness gauge 102 • Thimble 99
ENGLISH CUSTOMARY MEASURING SYSTEM The English customary measuring system was established about A.D. 1100 in England during the reign of Henry I. The foot was determined to be 12 inches and was taken from the length of a typical foot. The yard
(36 inches) was determined to be the length from King Henry’s nose to the end of his outstretched hand. The mile came from Roman days and was originally defined as the distance traveled by a soldier in 1,000 paces or steps. Other English units, such as the pound (weight) and volume (gallon), evolved over the years from Roman and English measurements. The Fahrenheit temperature scale was created by Gabriel Fahrenheit (1686–1736) and he used 100°F as the temperature of the human body, which he missed by 1.4 degrees (98.6°F is
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?
FREQUENTLY ASKED QUESTION
What Weighs a Gram?
3/16
To better understand the metric system measurements, it is often helpful to visualize a certain object and relate it to a metric unit of measure. For example, the following objects weigh about 1 gram.
1/16
• A dollar bill • A small paper clip
7/16 5/16
11/16 9/16
3/8
1/8 1/4
15/16
13/16
5/8
7/8 3/4
1/2
1
considered now to be normal temperature). On the Fahrenheit scale, water freezes at 32°F and water boils at 212°F.
METRIC SYSTEM OF MEASURE Most of the world uses the metric system of measure. The metric system was created in the late 1700s in France and used the physical world for the basis of the measurements. For example, the meter was defined as being 1/40,000,000 of the circumference of the earth (the distance around the earth at the poles). The Celsius temperature scale developed by Anders Celsius (1701–1744) used the freezing point of water as 0°C (32°F) and the boiling point of water as 100°C (212°F). Other units include a liter of water, which was then used as a standard of weight where 1 liter of water (about 1 quart) weighs 1 kilogram (1,000 grams). Units of measure are then divided or multiplied by 10, 100, and 1,000 to arrive at usable measurements. For example, a kilometer is 1,000 meters and is the most commonly used metric measurement for distance for travel. Other prefixes include:
1
2
FIGURE 12–1 A rule showing that the larger the division, the longer the line.
m ⫽ milli ⫽ 1/1,000 k ⫽ kilo ⫽ 1,000 M ⫽ mega ⫽ 1,000,000
LINEAR METRIC MEASUREMENTS 1 kilometer ⫽ 0.62 mile 1 meter ⫽ 39.37 inches 1 centimeter (1/100 meter) ⫽ 0.39 inch 1 millimeter (1/1,000 meter) ⫽ 0.039 inch
VOLUME MEASUREMENT
FIGURE 12–2 A plastic rule that has both inches and centimeters. Each line between the numbers on the centimeters represents 1 millimeter because there are 10 millimeters in 1 centimeter.
1 cc (cubic centimeter) ⫽ 0.06 cubic inch 1 liter ⫽ 0.26 U.S. gallon (about 1 quart)
WEIGHT MEASUREMENT 1 gram ⫽ 0.035 ounce 1 kilogram (1,000 grams) ⫽ 2.2 pounds
LINEAR MEASUREMENTS (TAPE MEASURE/RULE)
PRESSURE MEASUREMENTS 1 kilopascal (kPa) ⫽ 0.14 pound per square inch (6.9 kPa ⫽ 1 PSI) 1 bar ⫽ 14.5 pounds per square inch
DERIVED UNITS
All units of measure, except for the base units, are a combination of units that are referred to as derived units of measure. Some examples of derived units include:
1 inch 1/2 inch 1/4 inch
Torque
1/8 inch
Velocity
1/16 inch
Density Energy Power
98
A tape measure or machinist rule divides inches into smaller units. Each smaller unit is drawn with a line shorter than the longer unit. The units of measure starting with the largest include:
CHAPTER 1 2
Some rules show 1/32 of an inch. SEE FIGURE 12–1. A metric scale is also included on many tape measures and machinists rules. SEE FIGURE 12–2.
CRANKSHAFT MEASUREMENT
Even though the connecting rod journals and the main bearing journals are usually different sizes, they both can and should be measured for out-of-round and taper. SEE FIGURE 12–7.
MICROMETER A micrometer is the most used measuring instrument in engine service and repair. SEE FIGURE 12–3. The thimble rotates over the sleeve on a screw that has 40 threads per inch. Every revolution of the thimble moves the spindle 0.025 in. The thimble is graduated into 25 equally spaced lines; therefore, each line represents 0.001 in. Every micrometer should be checked for calibration on a regular basis. SEE FIGURES 12–4 THROUGH 12–6.
OUT-OF-ROUND. A journal should be measured in at least two positions across the diameter and every 120 degrees around the journal, as shown in FIGURE 12–8, for an example of the six readings. Calculate the out-of-round measurement by subtracting the lowest reading from the highest reading for both A and B positions. Position A: 2.0000 ⫺ 1.9995 ⫽ 0.0005 in. Position B: 2.0000 ⫺ 1.9989 ⫽ 0.0011 in.
MEASURING FACES
The maximum out-of-round measurement occurs in position B (0.0011 in.), which is the measurement that should be used to compare against factory specifications to determine if any machining will be necessary.
SPINDLE ANVIL
LOCK NUT SLEEVE 0
TAPER. To determine the taper of the journal, compare the readings in the same place between A and B positions and subtract the lower reading from the higher reading. For example:
5
1
0
THIMBLE
Position A
RATCHET STOP
FIGURE 12–3 A typical micrometer showing the names of the parts. The sleeve may also be called the barrel or stock.
Position B
2.0000
⫺
2.0000
⫽ 0.0000
1.9999
⫺
1.9999
⫽ 0.0000
1.9995
⫺
1.9989
⫽ 0.0006
Use 0.0006 in. as the taper for the journal and compare with factory specifications.
GAUGE ROD 0
0
CAMSHAFT MEASUREMENT The journal of the camshaft(s) can also be measured using a micrometer and compared with factory specifications for taper and out-of-round. SEE FIGURE 12–9. NOTE: On overhead valve (pushrod) engines, the camshaft journal diameter often decreases slightly toward the rear of the engine. Overhead camshaft engines usually have the same journal diameter.
FIGURE 12–4 All micrometers should be checked and calibrated as needed using a gauge rod.
0.0212 INCH (a)
0.0775 INCH (b)
0.5280 INCH (c)
FIGURE 12–5 The three micrometer readings are (a) 0.0212 in.; (b) 0.0775 in.; (c) 0.5280 in. These measurements used the vernier scale on the sleeve to arrive at the ten-thousandth measurement. The number that is aligned represents the digit in the ten-thousandth place. ME ASU RI N G SYST E M S A N D T OOL S
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0.187 MM
3.601 MM
(a)
5.5350 MM
(b)
(c)
FIGURE 12–6 Metric micrometer readings that use the vernier scale on the sleeve to read to the nearest 0.001 millimeter. The arrows point to the final reading for each of the three examples.
120°
120°
120°
FIGURE 12–9 Camshaft journals should be measured in three locations, 120 degrees apart, to check for out-of-round. The cam lift can also be measured with a micrometer and compared with factory specifications, as shown in FIGURE 12–10. 0
1
5
0
TELESCOPIC GAUGE
FIGURE 12–7 Using a micrometer to measure the connecting rod journal for out-of-round and taper.
2.0000"
2.0000" 1.9999"
120° 120° A
B
120° A
CHAPTER 1 2
Camshaft bearing ( SEE FIGURE 12–12.)
Main bearing bore (housing bore) measurement
Connecting rod bore measurement
1.9999" 120° 120°
1.9995"
120°
1.9989"
SMALL-HOLE GAUGE
B
FIGURE 12–8 Crankshaft journal measurements. Each journal should be measured in at least six locations, but also in position A and position B and at 120-degree intervals around the journal.
100
A telescopic gauge is used with a micrometer to measure the inside diameter of a hole or bore. The cylinder bore can be measured by inserting a telescopic gauge into the bore and rotating the handle lock to allow the arms of the gauge to contact the inside bore of the cylinder. Tighten the handle lock and remove the gauge from the cylinder. Use a micrometer to measure the telescopic gauge. SEE FIGURE 12–11. A telescopic gauge can also be used to measure the following:
A small-hole gauge (also called a split-ball gauge) is used with a micrometer to measure the inside diameter of small holes such as a valve guide in a cylinder head. SEE FIGURES 12–13 AND 12–14.
0
1
5
0
(a)
FIGURE 12–10 Checking a camshaft for wear by measuring the lobe height with a micrometer.
TELESCOPIC GAUGE
OUTSIDE MICROMETER (b)
FIGURE 12–12 (a) A telescopic gauge being used to measure the inside diameter (ID) of a camshaft bearing. (b) An outside micrometer used to measure the telescopic gauge.
(a)
?
FREQUENTLY ASKED QUESTION
What Is the Difference Between the Word Gage and Gauge? The word gauge means “measurement or dimension to a standard of reference.” The word gauge can also be spelled gage. Therefore, in most cases, the words mean the same.
(b)
FIGURE 12–11 When the head is first removed, the cylinder taper and out-of-round should be checked below the ridge (a) and above the piston when it is at the bottom of the stroke (b).
INTERESTING NOTE: One vehicle manufacturing representative told me that gage was used rather than gauge because even though it is the second acceptable spelling of the word, it is correct and it saved the company a lot of money in printing costs because the word gage has one less letter! One letter multiplied by millions of vehicles with gauges on the dash and the word gauge used in service manuals adds up to a big savings to the manufacturer.
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DIAL
KNIFE EDGE JAWS TO MEASURE INSIDE DIAMETERS
ROD USED TO MEASURE DEPTH OF RECESSES
BLADE
OUTSIDE JAWS USED TO MEASURE OUTSIDE DIAMETERS
(a) EACH SMALL LINE IS EQUAL TO 0.002"
80 70
FIGURE 12–13 Cutaway of a valve guide with a hole gauge adjusted to the hole diameter.
90 0 10
20 30 40
60
4 5 6 7 8 9
5"
5
1 2 3 4 5
50
50
40
60
30 20
70 10 0 90
80
0.5"
ADD READING ON BLADE (5.5") TO READING ON DIAL (0.036") TO GET FINAL TOTAL MEASUREMENT (5.536")
(b) 0
1
5
0
FIGURE 12–15 (a) A typical vernier dial caliper. This is a very useful measuring tool for automotive engine work because it is capable of measuring inside, outside, and depth measurements. (b) To read a vernier dial caliper, simply add the reading on the blade to the reading on the dial.
FIGURE 12–14 The outside of a hole gauge being measured with a micrometer.
VERNIER DIAL CALIPER A vernier dial caliper is normally used to measure length, inside and outside diameters, and depth. SEE FIGURE 12–15.
FIGURE 12–16 A group of feeler gauges (also known as thickness gauges), used to measure between two parts. The long gauges on the bottom are used to measure the piston-to-cylinder wall clearance.
FEELER GAUGE A feeler gauge (also known as a thickness gauge) is an accurately manufactured strip of metal that is used to determine the gap or clearance between two components. SEE FIGURE 12–16.
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A feeler gauge can be used to check the following:
Piston ring gap ( SEE FIGURE 12–17.)
Piston ring side clearance
Connecting rod side clearance
Piston-to-wall clearance
FEELER GAUGE
DIAL INDICATOR
PISTON RING
FIGURE 12–17 A feeler gauge, also called a thickness gauge, is used to measure the small clearances such as the end gap of a piston ring.
FIGURE 12–19 A dial indicator is used to measure valve lift during flow testing of a high-performance cylinder head.
FIGURE 12–18 A straightedge is used with a feeler gauge to determine if a cylinder head is warped or twisted.
STRAIGHTEDGE A straightedge is a precision ground metal measuring gauge that is used to check the flatness of engine components when used with a feeler gauge. A straightedge is used to check the flatness of the following:
Cylinder heads ( SEE FIGURE 12–18.)
Cylinder block deck
Straightness of the main bearing bores (saddles)
DIAL INDICATOR A dial indicator is a precision measuring instrument used to measure crankshaft end play, crankshaft runout, and valve guide wear. A dial indicator can be mounted three ways, including:
Magnetic mount. This is a very useful method because a dial indicator can be attached to any steel or cast iron part.
FIGURE 12–20 A dial bore gauge is used to measure cylinders and other engine parts for out-of-round and taper conditions.
Clamp mount. A clamp-mounted dial indicator is used in many places where a mount could be clamped.
Threaded rod. Using a threaded rod allows the dial indicator to be securely mounted, such as shown in FIGURE 12–19.
DIAL BORE GAUGE A dial bore gauge is an expensive, but important, gauge used to measure cylinder taper and out-of-round as well as main bearing (block housing) bore for taper and out-of-round. SEE FIGURE 12–20. A dial bore gauge has to be adjusted to a dimension, such as the factory specifications. The reading on the dial bore gauge then indicates plus (⫹) or minus (⫺) readings from the predetermined dimension. This is
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why a dial bore is best used to measure taper and out-of-round because it shows the difference in cylinder or bore rather than an actual measurement.
DEPTH MICROMETER A depth micrometer is similar to a conventional micrometer except that it is designed to measure the depth from a flat surface. SEE FIGURE 12–21. FIGURE 12–21 A depth micrometer being used to measure the height of the rotor of an oil pump from the surface of the housing.
REVIEW QUESTIONS 1. Explain how a micrometer is read. 2. Describe how to check a crankshaft journal for out-of-round and taper. 3. List engine components that can be measured with the help of a telescopic gauge.
4. List the gaps or clearances that can be measured using a feeler (thickness) gauge. 5. Explain why a dial bore gauge has to be set to a dimension before using.
CHAPTER QUIZ 1. The threaded movable part that rotates on a micrometer is called the ______________. a. Sleeve b. Thimble c. Spindle d. Anvil
6. Which of the following cannot be measured using a feeler gauge? a. Valve guide clearance b. Piston-ring gap c. Piston-ring side clearance d. Connecting rod side clearance
2. To check a crankshaft journal for taper, the journal should be measured in at least how many locations? a. One b. Two c. Four d. Six
7. Which of the following cannot be measured using a straightedge and a feeler gauge? a. Cylinder head flatness b. Block deck flatness c. Straightness of the main bearing bores d. Straightness of the cylinder bore
3. To check a crankshaft journal for out-of-round, the journal should be measured in at least how many locations? a. Two b. Four c. Six d. Eight
8. Which measuring gauge needs to be set up (adjusted) to a fixed dimension before use? a. Dial indicator b. Dial bore gauge c. Vernier dial gauge d. Micrometer
4. A telescopic gauge can be used to measure a cylinder bore if what other measuring device is used to measure the telescopic gauge? a. Micrometer b. Feeler gauge c. Straightedge d. Dial indicator
9. The freezing point of water is ______________. a. 0°C b. 32°F c. 0°F d. Both a and b
5. To directly measure the diameter of a valve guide in a cylinder head, use a micrometer and a ______________. a. Telescopic gauge b. Feeler gauge c. Small-hole gauge d. Dial indicator
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10. Which metric unit of measure is used for volume measurement? a. Meter b. cc c. Centimeter d. Millimeter
S E C T I O N
IV
Principles, Math, and Calculations 14 Math, Charts, and Calculations
13 Scientific Principles and Materials
chapter
13
SCIENTIFIC PRINCIPLES AND MATERIALS
OBJECTIVES: After studying Chapter 13, the reader will be able to: • Describe Newton’s Laws of Motion. • Explain kinetic energy and why it is so important to brake design. • Discuss mechanical advantage and how it is used in a vehicle. • Define torque and horsepower. • Describe sound and acoustics. • Explain bases and acids. • Discuss the gas laws. • Explain the coefficient of friction. • Describe the difference between heat and temperature. • Describe the methods used to identify plastic, iron, steel, and aluminum. KEY TERMS: Acid material 111 • Alkaline 111 • Brake 108 • Brake horsepower (bhp) 108 • BTU (British Thermal Unit) 110 • Caustic material 111 • Celsius (centigrade) 110 • Conduction 110 • Conductor 110 • Convection 110 • Dynamometer (dyno or dyn) 107 • Energy 106 • Fahrenheit 111 • First-class lever 109 • Force 106 • Fulcrum 109 • Horsepower 107 • Hypothesis 105 • Inertia 109 • Insulator 110 • Kinetic energy 106 • Leverage 109 • Mass 109 • Mechanical advantage 110 • Newton’s laws of motion 108 • Pedal ratio 110 • PH 111 • Potential energy 106 • Power 107 • Propagation 112 • Radiation 110 • Root cause 105 • Scientific method 105 • Second-class lever 109 • Third-class lever 109 • Torque 106 • Weight 109 • Work 106 • Wrought alloys 113
SCIENTIFIC METHOD The scientific method is a series of steps taken to solve a problem. These steps help eliminate errors and to achieve an accurate result. The scientific method is the foundation of automotive diagnosis. A scientific method involves the following steps: STEP 1
Observe the conditions or problem and define or describe the problem.
STEP 2
Formulate an explanation that could be the cause of the problem.
STEP 3
Use the explanation (hypothesis) to test to see if it matches the existing problem. If not, then return to step 2 to formulate another explanation.
STEP 4
After the explanation has proved to be a possible solution to a problem, additional tests should be performed to verify that the method works all of the time.
USING THE SCIENTIFIC METHOD While a service technician will not perform research, using a scientific approach to problem solving is very important. This means that every fault should be investigated to determine the root cause rather than solving what at first is thought to be the problem or fault. The root cause is the true cause of a failure, which may not be noticed at first. Many service technicians ask themselves “why” when they discover a fault. Often this leads to another possible problem and then the technician should ask another “why.” This scientific method of finding the root cause of an automotive problem is often called the “five whys.” By the time the technician has asked “why” five times, the root cause is usually discovered. EXAMPLES OF THE FIVE WHYS As an example of using a scientific method approach to automotive faults, an owner may state that the vehicle does not start and the battery appears to be dead. Therefore, applying the five whys (scientific approach) first ask why:
First why—What caused the battery to become discharged? To answer this question requires observation and the creating
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105
1 FOOT
10 POUNDS
HEAT AND LIGHT
MECHANICAL
FIGURE 13–2 Torque is a twisting force equal to the distance from the pivot point times the force applied expressed in units called pound-feet (lb-ft) or Newton-meters (N-m).
10 FEET 100 LBS
CHEMICAL
SOUND
FIGURE 13–1 Energy, which is the ability to perform work, exists in many forms.
of a hypothesis, such as “is the battery defective” or “did the customer leave the lights on?” This requires questioning the owner and testing the battery.
Second why—Assume that the battery was in good condition but discharged. Now the technician should ask the second why. “Why did the battery become discharged?” This means that a battery ignition off drain test needs to be performed as well as testing of the charging system. Assume the battery drain test was okay, but that the charging system was not working properly.
Third why—The charging system was found to be not working correctly. A visual inspection found that the alternator drive belt was not tight enough to properly operate the alternator. The technician needs to ask the third why, “Why is the accessory drive belt still loose?”
Fourth why—“Why was the accessory drive belt loose?” The cause could be a defective tensioner. If the tensioner itself was not a problem, then another “why” needs to be asked.
Fifth why—If the accessory belt and belt tensioner were okay, then further investigation would be needed to find the root cause. For example, “Is one of the tensioner retaining bolts loose, maybe from a previous repair?” This could be the root cause.
FIGURE 13–3 Work is calculated by multiplying force times distance. If you push 100 pounds 10 feet, you have done 1,000 foot-pounds of work. to useful energy, such as the potential energy stored in a battery or a vehicle at the top of a hill. In both of these cases, there is no energy being released but if the battery were connected to an electrical load, such as a light bulb, or the vehicle starts moving down the hill, the energy is being released.
TORQUE Torque is the term used to describe a rotating force that may or may not result in motion. Torque is measured as the amount of force multiplied by the length of the lever through which it acts. If a one-foot-long wrench is used to apply 10 pounds of force to the end of the wrench to turn a bolt, then 10 pound-feet of torque is being applied. SEE FIGURE 13–2. The metric unit for torque is Newton-meters because Newton is the metric unit for force and the distance is expressed in meters. 1 pound-foot ⫽ 1.3558 Newton-meters 1 Newton-meter ⫽ 0.7376 pound-foot
WORK ENERGY PRINCIPLES Energy is the ability or the capacity to do work. There are many forms of energy, but chemical, mechanical, and electrical energy are the most familiar kinds involved in the operation of an automobile. SEE FIGURE 13–1. Energy in the form of a moving object is called kinetic energy. An example of kinetic energy is a moving vehicle. Energy is called potential energy if it is capable of being changed
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Work is defined as actually accomplishing movement when force (torque) is applied to an object. A service technician can apply torque to a bolt in an attempt to loosen it, yet no work is done until the bolt actually moves. Work is calculated by multiplying the applied force (in pounds) by the distance the object moves (in feet). If you applied 100 pounds of force to move an object 10 feet, then you accomplished 1,000 foot-pounds of work (100 pounds ⫻ 10 feet ⫽ 1,000 foot pounds). SEE FIGURE 13–3.
Newton-Meters to Pound-Feet Conversion Chart (1 N-m ⫽ 0.074 lb-ft)
Pound-Feet to Newton-Meters Conversion Chart (1 lb-ft ⫽ 1.4 N-m) Lb-ft
N-m
Lb-ft
N-m
Lb-ft
N-m
1.4
26
36.4
51
71.4
76
106.4
2
2.8
27
37.8
52
72.8
77
107.8
3
4.2
28
39.2
53
74.2
78
109.2
58.5
4
5.6
29
40.6
54
75.6
79
110.6
59.2
5
7.0
30
42.0
55
77.0
80
112.0
81
59.9
6
8.4
31
43.4
56
78.4
81
113.4
42.2
82
60.7
7
9.8
32
44.8
57
79.8
82
114.8
42.9
83
61.4
8
11.2
33
46.2
58
81.2
83
116.2
Lb-ft
N-m
Lb-ft
N-m
Lb-ft
N-m
Lb-ft
N-m
Lb-ft
1
0.74
26
19.2
51
37.7
76
56.2
1
2
1.5
27
20.0
52
38.5
77
57.0
3
2.2
28
20.7
53
39.2
78
57.7
4
3.0
29
21.5
54
40.0
79
5
3.7
30
22.2
55
40.7
80
6
4.4
31
22.9
56
41.4
7
5.2
32
23.7
57
8
5.9
33
24.4
58
N-m
9
6.7
34
25.2
59
43.7
84
62.2
9
12.6
34
47.6
59
82.6
84
117.6
10
7.4
35
25.9
60
44.4
85
62.9
10
14.0
35
49.0
60
84.0
85
119.0
11
8.1
36
26.6
61
45.1
86
63.6
11
15.4
36
50.4
61
85.4
86
120.4
12
8.9
37
27.4
62
45.9
87
64.4
12
16.8
37
51.8
62
86.8
87
121.8
13
9.6
38
28.1
63
46.6
88
65.1
13
18.2
38
53.2
63
88.2
88
123.2
14
10.4
39
28.9
64
47.4
89
65.9
14
19.6
39
54.6
64
89.6
89
124.6
15
11.1
40
29.6
65
48.1
90
66.6
15
21.0
40
56.0
65
91.0
90
126.0
16
11.8
41
30.3
66
48.8
91
67.3
16
22.4
41
57.4
66
92.4
91
127.4
17
12.6
42
31.1
67
49.6
92
68.1
17
23.8
42
58.8
67
93.8
92
128.8
18
13.3
43
31.8
68
50.3
93
68.8
18
25.2
43
60.2
68
95.2
93
130.2
19
14.1
44
32.6
69
51.0
94
69.6
19
26.6
44
61.6
69
96.6
94
131.6
20
14.8
45
33.3
70
51.8
95
70.3
20
28.0
45
63.0
70
98.0
95
133.0
21
15.5
46
34.0
71
52.5
96
71.0
21
29.4
46
64.4
71
99.4
96
134.4
22
16.3
47
34.8
72
53.3
97
71.8
22
30.8
47
65.8
72
100.8
97
135.8
23
17.0
48
35.5
73
54.0
98
72.5
23
32.2
48
67.2
73
102.2
98
137.2
24
17.8
49
36.3
74
54.8
99
73.3
24
33.6
49
68.6
74
103.6
99
138.6
25
18.5
50
37.0
75
55.5
100
74.0
25
35.0
50
70.0
75
105.0
100
140.0
?
200 POUNDS (91 KG)
FREQUENTLY ASKED QUESTION
What Is the Difference between Torque and Work? The designations for torque and work are often confusing. Torque is expressed in pound-feet because it represents a force exerted a certain distance from the object and acts as a lever. Work, however, is expressed in footpounds because work is the movement over a certain distance (feet) multiplied by the force applied (pounds). Engines produce torque and service technicians exert torque represented by the unit pound-feet.
POWER The term power means the rate of doing work. Power equals work divided by time. Work is achieved when a certain amount of mass (weight) is moved a certain distance by a force. If the object is moved in 10 seconds or 10 minutes does not make a difference in the amount of work accomplished, but it does affect the amount of power needed. Power is expressed in units of foot-pounds per minute.
165 FEET (50 M) 165 FEET (50 M) PER MINUTE
FIGURE 13–4 One horsepower is equal to 33,000 foot-pounds (200 lbs ⫻ 165 ft) of work per minute.
HORSEPOWER The power an engine produces is called horsepower (hp). One horsepower is the power required to move 550 pounds one foot in one second, or 33,000 pounds one foot in one minute (550 lb ⫻ 60 sec ⫽ 33,000 lb). This is expressed as 500 foot-pounds (ft-lb) per second or 33,000 foot-pounds per minute. SEE FIGURE 13–4. The actual horsepower produced by an engine is measured with a dynamometer. A dynamometer (often abbreviated as dyno
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107
or dyn) places a load on the engine and measures the amount of twisting force the engine crankshaft places against the load. The load holds the engine speed, so it is called a brake. The horsepower derived from a dynamometer is called brake horsepower (bhp). The dynamometer actually measures the torque output of the engine. Torque is a rotating force that may or may not cause movement. The horsepower is calculated from the torque readings at various engine speeds (in revolutions per minute or RPM). Horsepower is torque times RPM divided by 5252. Torque ⫻ RPM Horsepower ⫽ 5252
3,000 LB
= 90,301 FT-LB
30 MPH
= 180,602 FT-LB
6,000 LB 30 MPH
Torque is what the driver “feels” as the vehicle is being accelerated. A small engine operating at a high RPM may have the same horsepower as a large engine operating at a low RPM.
FIGURE 13–5 Kinetic energy increases in direct proportion to the weight of the vehicle.
NOTE: As can be seen by the formula for horsepower, the higher the engine speed for a given amount of torque, the greater the horsepower.
Engineers calculate kinetic energy using the following formula:
NEWTON’S LAWS OF MOTION Sir Isaac Newton (1643–1727) was an English physicist and mathematician who developed many theories of science, including three laws of motion. 1. Newton’s first law of motion states that an object at rest tends to stay at rest and an object in motion tends to stay in motion unless acted on by an outside force. For example, it requires a large force to get a vehicle that is stopped into motion. It also requires that a force be applied to slow and stop a vehicle that is in motion. 2. Newton’s second law of motion states that the force needed to move an object is proportional to the mass of the object multiplied by the acceleration rate of the object. This means that it requires a great deal more force to accelerate a heavy sport utility vehicle (SUV) than a small economy vehicle. The rate of acceleration also depends on the amount of force that is applied. 3. Newton’s third law of motion states that for every action, there is an opposite and equal reaction. For example, when the airfuel mixture is ignited in an engine, the force is exerted on the piston, which is forced downward, which causes the crankshaft of the engine to rotate. The opposite action is applied to the cylinder head of the engine and applies the same force although this part is designed not to move.
KINETIC ENERGY Kinetic energy is a fundamental form of mechanical energy. It is the energy of mass in motion. Every moving object possesses kinetic energy, and the amount of that energy is determined by the object’s mass and speed. The greater the mass of an object and the faster it moves, the more kinetic energy it possesses. Even at low speeds, a moving vehicle has enough kinetic energy to cause serious injury and damage. The job of the brake system is to dispose of that energy in a safe and controlled manner.
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2
mv ⫽ Ek 29.9 where: m ⫽ mass or weight of the vehicle in pounds v ⫽ velocity of the vehicle in miles per hour Ek ⫽ kinetic energy in foot-pounds (ft-lb) Another way to express this equation is as follows. weight ⫻ speed 29.9
2
⫽ kinetic energy
If a 3,000-pound vehicle traveling at 30 mph is compared to a 6,000-pound vehicle also traveling at 30 mph as shown in FIGURE 13–5, the equations for computing their respective kinetic energies look like this: 2
3,000 lb ⫻ 30 mph ⫽ 90,301 ft-lb 29.9 2
6,000 lb ⫻ 30 mph ⫽ 180,602 ft-lb 29.9 The results show that when the weight of a vehicle is doubled from 3,000 to 6,000 pounds, its kinetic energy is also doubled from 90,301 foot-pounds to 180,602 foot-pounds. In mathematical terms, kinetic energy increases proportionally as weight increases. In other words, if the weight of a moving object doubles, its kinetic energy also doubles. If the weight quadruples, the kinetic energy becomes four times as great. If a 3,000-pound vehicle traveling at 30 mph is compared to the same vehicle traveling at 60 mph ( FIGURE 13–6), the equations for computing their respective kinetic energies look like this: 2
3,000 lb ⫻ 30 mph ⫽ 90,301 ft-lb 29.9 2
3,000 lb ⫻ 60 mph ⫽ 361,204 ft-lb 29.9 The results show that the vehicle traveling at 30 mph has over 90,000 foot-pounds of kinetic energy, but at 60 mph the figure increases to over 350,000 foot-pounds. In fact, at twice the speed, the vehicle has exactly four times as much kinetic energy. If the speed were doubled again to 120 mph, the amount of kinetic energy
1 FT 3,000 LB
2 FT
= 90,301 FT-LB
30 MPH
5-LB FORCE
FULCRUM
3,000 LB
= 361,204 FT-LB
60 MPH
10-LB WEIGHT
FIGURE 13–7 A first-class lever increases force and changes the direction of the force.
FIGURE 13–6 Kinetic energy increases as the square of any increase in vehicle speed.
?
LEVER
1½ FT
1½ FT
FREQUENTLY ASKED QUESTION
What Is the Difference Between Mass and Weight? Mass is the amount of matter in an object. One of the properties of mass is inertia. Inertia is the resistance to being put in motion and the tendency to remain in motion once it is set in motion. The weight of an object is the force of gravity on the object and may be defined as the mass times the acceleration of gravity. Therefore, mass means the property of an object and weight is a force.
TECH TIP
5-LB FORCE
FULCRUM 10-LB WEIGHT
LEVER
FIGURE 13–8 A second-class lever increases force in the same direction as it is applied.
process and the selection of brake components. Inertia is defined by Isaac Newton’s first law of motion, which states that a body at rest tends to remain at rest, and a body in motion tends to remain in motion in a straight line unless acted upon by an outside force.
MECHANICAL PRINCIPLES
Brakes Cannot Overcome the Laws of Physics No vehicle can stop on a dime. The energy required to slow or stop a vehicle must be absorbed by the braking system. All drivers should be aware of this fact and drive at a reasonable speed for the road and traffic conditions.
would grow to almost 1,500,000 foot-pounds! In mathematical terms, kinetic energy increases as the square of its speed. In other words, if the speed of a moving object doubles (2), the kinetic energy becomes four times as great (22 ⫽ 4). And if the speed quadruples (4), say from 15 to 60 mph, the kinetic energy becomes 16 times as great (42 ⫽ 16). This is the reason speed has such an impact on kinetic energy.
KINETIC ENERGY AND BRAKE DESIGN
The relationships between weight, speed, and kinetic energy have significant practical consequences for the brake system engineer. If vehicle A weighs twice as much as vehicle B, it needs a brake system that is twice as powerful. But if vehicle C has twice the speed potential of vehicle D, it needs brakes that are, not twice, but four times more powerful.
INERTIA Although brake engineers take both weight and speed capability into account when designing a brake system, these are not the only factors involved. Another physical property, inertia, also affects the braking
The primary mechanical principle used to increase application force in every brake system is leverage. In the science of mechanics, a lever is a simple machine that consists of a rigid object, typically a metal bar that pivots about a fixed point called a fulcrum. There are three basic types of levers, but the job of all three is to change a quantity of energy into a more useful form. A first-class lever increases the force applied to it and also changes the direction of the force. SEE FIGURE 13–7. With a first-class lever, the weight is placed at one end while the lifting force is applied to the other. The fulcrum is positioned at some point in between. If the fulcrum is placed twice as far from the long end of the lever as from the short end, a 10-pound weight on the short end can be lifted by only a 5-pound force at the long end. However, the short end of the lever will travel only half as far as the long end. Moving the fulcrum closer to the weight will further reduce the force required to lift it, but it will also decrease the distance the weight is moved. A second-class lever increases the force applied to it and passes it along in the same direction. SEE FIGURE 13–8. With a second-class lever, the fulcrum is located at one end while the lifting force is applied at the other. The weight is positioned at some point in between. If a 10-pound weight is placed at the center of the lever, it can be lifted by only a 5-pound force at the end of the lever. However, the weight will only travel half the distance the end of the lever does. As the weight is moved closer to the fulcrum, the force required to lift it, and the distance it travels, are both reduced. A third-class lever actually reduces the force applied to it, but the resulting force moves farther and faster. SEE FIGURE 13–9.
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109
1½ FT
MASTER CYLINDER
1½ FT
FULCRUM
FULCRUM LEVER
20-LB FORCE
2 IN. 10-LB WEIGHT
50-LB FORCE
FIGURE 13–9 A third-class lever reduces force but increases the speed and travel of the resulting work.
With a third-class lever, the fulcrum is located at one end and the weight is placed at the other. The lifting force is applied at some point in between. If a 10-pound weight is placed at the end of the lever, it can be lifted by a 20-pound force applied at the middle of the lever. Although the force required to move the weight has doubled, the weight is moved twice as far and twice as fast as the point on the lever where the force was applied. The closer to the fulcrum the lifting force is applied, the greater the force required by the weight and the farther and faster the weight will move. The levers in brake systems are used to increase force, so they are either first- or second-class. Second-class levers are the most common, and the service brake pedal is a good example. In a typical suspended brake pedal, the pedal arm is the lever, the pivot point is the fulcrum, and the force is applied at the foot pedal pad. SEE FIGURE 13–10. The force applied to the master cylinder by the pedal pushrod attached to the pivot is much greater than the force applied at the pedal pad, but the pushrod does not travel nearly as far. Leverage creates a mechanical advantage that, at the brake pedal, is called the pedal ratio. For example, a pedal ratio of 5 to 1 is common for manual brakes, which means that a force of 10 pounds at the brake pedal will result in a force of 50 pounds at the pedal pushrod. In practice, leverage is used at many points in both the service and parking brake systems to increase braking force while making it easier for the driver to control the amount of force applied.
10 IN.
LEVER 10-LB FORCE
FIGURE 13–10 This brake pedal assembly provides a 5:1 mechanical advantage because a 10-lb force input results in a 50-lb force into the master cylinder.
TECH TIP Conductors and Insulators If a material is a good conductor of heat, it is also a good conductor of electricity. Most conductors are metals, such as steel, copper, aluminum, and brass. Most insulators are nonmetals, such as plastic and rubber. Therefore, if a material does not conduct heat, it usually will not conduct electricity.
?
FREQUENTLY ASKED QUESTION
How Does a Coat Keep You Warm? A coat is worn in cold weather to keep warm. Does it keep the cold out or the heat in? Actually, both, but because heat travels from a warm object (human body) to a colder object (outside cold air), the primary purpose of a coat is to keep the body heat from escaping into the cold air.
HEAT AND TEMPERATURE Heat and temperature are related but are not the same. Temperature is the intensity of the heat source, whereas heat is the quantity of heat. For example, the heat from a match and a large fire may measure the same temperature, but the amount of heat generated by the fire is far greater than the amount of heat generated by a single match.
HEAT Heat is measured in units called British Thermal Units, abbreviated BTUs. One BTU is the amount of heat needed to raise the temperature of one pound of water one degree Fahrenheit. For example, room heaters and air conditioners are rated in how many BTUs per hour can be added (heater) or removed (air conditioner) from a space in one hour. Heat energy can be transferred by three ways, including:
Conduction—Conduction is the process of the heat traveling from a hotter part to a colder part of the same object or by direct contact. For example, if one end of a steel bar is heated, then the heat will travel by conduction toward the colder areas of the bar. Also, if the metal were touched, heat would travel from the steel bar to the finger. Metals are good conductors of heat, whereas plastic, rubber, and ceramics are poor conductors of heat and are called insulators.
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Convection—Convection is the transfer of heat through a liquid or a gas, which causes it to rise while the cooler liquid or gas falls within a container. A hot air balloon is an example where hot gas in the balloon causes it to rise above the surrounding cooler air.
Radiation—Radiation is a method of energy transfer where heat is transmitted through the air. Heat from the sun is transmitted through the atmosphere where it heats the ground. Heat can be felt above a hot stove.
TEMPERATURE
Temperature is the measurement of the ability to give up or absorb heat from another body. Heat always flows from a warmer object to a colder object. Temperature is measured using two scales: 1. Celsius (also called centigrade). The Celsius scale was devised by taking the freezing point and the boiling point of water and dividing it into 100 equal parts.
?
FREQUENTLY ASKED QUESTION
What Is Thermodynamics? Thermodynamics is the study of the relationship among temperature, pressure, and volume changes. The laws of thermodynamics help engineers design and develop engines with higher efficiency. Thermodynamics is therefore used in the design of the cooling system, as well as in the engine, because the more heat created by the burning of fuel in the engine, the more power the engine can develop using the same or less amount of fuel.
?
FIGURE 13–11 A typical outdoor thermometer which is used to measure temperature, not heat.
Can Water and Acid Be Mixed Together? Acids have a very strong affinity for water and as a result, if water is poured into acid, the resulting reaction would be extremely violent and acid would be forced outward in all directions. Always pour acid into water, never water into acid. Technicians seldom need to work with acids because even battery electrolytes from the water and acid are premixed to help prevent the possibility of a technician creating a harmful reaction.
TECH TIP Quick and Easy Temperature Conversion Many service information and scan tool data are expressed in degrees Celsius, which is often confusing to those used to temperature expressed in Fahrenheit degrees. A quick and easy way to get an approximate conversion is to take the degrees in Celsius, double it, and add 25. For example, Celsius ⫻ 2 ⫹ 25 ⫽ approximate Fahrenheit degrees:
FREQUENTLY ASKED QUESTION
ACIDS AND BASES
0°C ⫻ 2 ⫽ 0 ⫹ 25 ⫽ 25°F (actual ⫽ 32°F) 10°C ⫻ 2 ⫽ 20 ⫹ 25 ⫽ 45°F (actual ⫽ 50°F) 15°C ⫻ 2 ⫽ 30 ⫹ 25 ⫽ 55°F (actual ⫽ 59°F) 20°C ⫻ 2 ⫽ 40 ⫹ 25 ⫽ 65°F (actual ⫽ 68°F) 25°C ⫻ 2 ⫽ 50 ⫹ 25 ⫽ 75°F (actual ⫽ 77°F) 30°C ⫻ 2 ⫽ 60 ⫹ 25 ⫽ 85°F (actual ⫽ 86°F) 35°C ⫻ 2 ⫽ 70 ⫹ 25 ⫽ 95°F (actual ⫽ 95°F) 40°C ⫻ 2 ⫽ 80 ⫹ 25 ⫽ 105°F (actual ⫽ 104°F) 45°C ⫻ 2 ⫽ 90 ⫹ 25 ⫽ 115°F (actual ⫽ 113°F) 50°C ⫻ 2 ⫽ 100 ⫹ 25 ⫽ 125°F (actual ⫽ 122°F)
2. Fahrenheit. The Fahrenheit scale was developed by Gabriel Fahrenheit (1686–1736), a German physicist who proposed the scale in 1724. He wanted to avoid using negative numbers, so the scale used had zero degrees representing the coldest outside air temperature he had ever measured and used his own body temperature to represent 100 degrees. Later, more accurate measurements indicate that average human body temperature to be 98.6 degrees so he was off by 1.4 degrees. Also, negative outside air temperatures can occur. SEE FIGURE 13–11 and the comparison chart. Temperature Symbol
Degree Celsius °C
Degree Fahrenheit °F
Boiling point of water
100.0
212.0
Average human body temperature
37.0
98.6
Average room temperature
20.0 to 25.0
68.0 to 77.0
Melting point of ice
0.0
32.0
ACIDS Acids are substances that can corrode metals and some can cause severe burns to the skin. Common household acids that are not harmful and taste sour include vinegar and lemon juice (citric acid). Stronger acids include:
Hydrochloric acid
Nitric acid
Battery acid
BASES A base is a substance that can also burn the skin if strong enough and is also referred to as alkaline. Common household bases are generally not harmful unless eaten and have a bitter taste, including baking soda, soap, and antacid, such as Milk of Magnesia®. Stronger bases, which can burn the skin include:
Lye (sodium hydroxide)
Bleach
Drain cleaner
pH SCALE
Most chemical cleaners used for cleaning carbontype deposits are a strong soap, or caustic material. A value called pH, measured on a scale from 1 to 14, is used to indicate the amount of chemical activity. The term pH is from the French word pouvoir hydrogine, meaning “hydrogen power.” Pure water is neutral. On the pH scale, water is pH 7. Caustic materials have pH numbers from 8 through 14. The higher the number, the stronger the caustic action will be. Acid materials have pH numbers from 6 through 1. The lower the number, the stronger the acid action will be. Caustic materials and acid materials neutralize each other, such as when baking soda (a caustic) is used to clean the outside of the battery
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(an acid surface). The caustic baking soda neutralizes any sulfuric acid that has been spilled or splashed on the outside of the battery.
TECH TIP
CAUTION: Whenever working with chemicals, eye protection must be used.
Wear Hearing Protection According to audiologists (hearing and speech doctors), a person should wear ear protection if the level of sound requires that your voice be raised in order to be heard. Any level that exceeds 90 dB requires the use of ear protection to avoid hearing loss. This means that ear protection should be worn when using a power mower or using an air tool, such as an air impact wrench or air ratchet.
GAS LAWS Gas laws are a set of characteristics that describe how gases act and the relationship between their temperature, pressure, and volume. Gas laws have application in most systems of the vehicle, including tires, air-conditioning systems, and anywhere else gases are present.
BOYLE’S LAW
Boyle’s law was first written in 1662 by Robert Boyle (1627–1691) and describes the relationship between volume and pressure of a gas in a closed container. Boyle’s law states that the volume of a gas varies inversely (opposite) with the pressure exerted against it in a closed container. Therefore, if a closed container is compressed, the volume of the gas inside is reduced but the pressure is increased.
CHARLES’S LAW Charles’s Law was first formulated about 1787 by a French scientist, Jacque Charles (1746–1823). According to Charles’s law when the temperature of a gas increases, the volume increases. When the temperature of a gas decreases, the volume decreases.
SOUND AND ACOUSTICS Sound is the movement of air which the ear interprets as sound. Sound travels through the air, which is called propagation. Propagation of sound is normally thought to be only transmitted through air, but liquids can also transmit sound waves. Sound has two properties:
Frequency. This is also called the pitch of the sound and is measured in Hertz or cycles per second. Normal hearing frequency ranges from as low as 20 Hertz to 20,000 Hertz. Very low frequencies, such as the heart beat, of one or two Hertz cannot be heard. High frequencies over 20,000 Hertz also cannot be detected by humans.
Intensity. The intensity of sound, which is also called loudness, is measured in decibels (dB) named for Alexander Graham Bell (1847–1922), the inventor of the telephone. Relative intensity (loudness), using the decibel scale, includes the following examples:
Whisper
10–20 dB
Normal conversation
60 dB
Thunder
110 dB
Threshold of pain
120 dB
ACOUSTICS Acoustics is the study of sound and how it is generated and transmitted. Acoustic engineers are employed by vehicle manufacturers to help reduce noise and designing methods to reduce or stop the noise from being transmitted into the passenger compartment. For example, according to acoustic engineers, about 80% of the noise created by the movement of the tires on the road is transmitted through the chassis and body of the vehicle. Only about 20% of the sound is transferred to the passenger compartment through the air.
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PLASTICS There are two basic types of plastic.
THERMOSET PLASTIC This type of plastic is changed chemically when cured and shaped and cannot be reheated or reformed. Rubber is an example of a thermoset plastic material that cannot be remelted and reformed after curing. Other examples of thermoset plastics include:
Bakelite (phenol formaldehyde resin)
Polyester resin
Epoxy resin
THERMOPLASTIC This type of plastic is flexible at room temperature. Thermoplastic can be recycled by grinding it into pieces and remolding it into another shape. Examples of thermoplastics include:
Polyethylene (PE)
Polyvinyl chloride (PVC)
Polystyrene (PS)
ABS (acrylonitrile butadiene styrene)
PA nylon (polyamides)
PLASTIC IDENTIFICATION While it is not important for the average service technician to determine what kind of plastic is being used for what application, it is important to know when restoring a part or refinishing a plastic part. For example, interior plastic parts can be made from the following plastic material:
Polypropylene plastic (PP)
Polyethylene (PE) ( SEE FIGURE 13–12)
ABS plastic
ABS/PVC plastic
Vinyl (PVC) plastic
Most large plastic pieces are labeled on the inside with letters, such as PP or PE. However, if no marking is visible, it is still possible to identify the type of plastic using a simple basic test. A painter will need to know the type of plastic if refinishing these parts. Often replacement plastic parts are available in only one color and must be painted to match the original when being replaced. A burn test is used to test if the plastic part is polypropylene or ABS plastic by performing the following steps: STEP 1
Remove a small piece from a hidden back side of the plastic part being tested.
STEP 2
Hold the small piece of plastic with tweezers and ignite the plastic.
STEP 3
Observe the burning of the plastic: • No visible smoke means that the plastic is polypropylene. • Visible black smoke means that the plastic is ABS.
of carbon is 0.01%. In other words, 100 points of carbon is equal to 1%. The percentage of carbon in steel has a huge input on the strength and characteristics of the steel. For example,
FIGURE 13–12 This interior plastic part is labeled PE-HD, which means polyethylene-high density.
STEP 4
To determine if a part to be painted is polyvinyl chloride, a copper wire test needs to be performed by heating a copper wire and then touching the heated wire to a hidden back side surface of the part being tested. After melting some plastic onto the copper wire, return the wire to the flame and observe the color of the flame. If the color of the flame is green/ blue or turquoise, then the plastic is polyvinyl chloride (vinyl).
After the type of plastic has been identified, then check with service information and paint literature to determine the proper paint and preparations needed to refinish the plastic part.
IRON AND STEEL Iron is a chemical element with a symbol of Fe. It is one of the most commonly available elements on earth and is refined from iron ore. Steel is made from iron after further refining. The main difference between iron and steel is the amount of carbon. The amount of carbon is critical to the strength and characteristics of iron and steel.
CAST IRON Cast iron contains carbon is usually in the shape of 0.004 inches long. Cast iron is used tions, including engine blocks, rear suspension components.
2% to 4% carbon and this flakes of graphite 0.001 to in many automotive applicaaxle assemblies, and some
DUCTILE CAST IRON
In ductile iron, the carbon in the alloy with silicon are small ball-shapes called spherloidols. Ductile iron is also called malleable iron and is used to make crankshafts.
GRAY CAST IRON
Gray cast iron is cast iron that has another element, silicon, in the alloy giving the metal a gray color. Gray cast iron is used for engine blocks. NOTE: Cast iron contains graphite, which acts as a lubricant when being machined. As a result, cooling oil or water is not needed when making cast iron brake rotors or brake drums.
SAE STEEL DESIGNATIONS Steels are designed by a system established by the Society of Automotive Engineers and includes numbers to indicate the main element used in the alloy, plus the “points of carbon.” One part
Mild (low carbon) steel has less than 20 points of carbon (0.02%). Mild steel is soft and easily formed but is not very strong. Common usage of low carbon steel is in tables and chairs and vehicle body parts where strength is not an issue.
Medium carbon steel usually has between 25 and 50 points of carbon (0.25% and 0.50%). This type of steel can be heat treated to create steel that is ductile (flexible) and yet has good strength. This type of steel is usually used in forgings and machined components.
High carbon steel usually has between 60 and 100 points (0.60% and 1.00%) of carbon and is very strong. It is commonly used in vehicle springs and can be hardened. CAUTION: Both medium carbon and high carbon steel can be hardened by heating and then cooling, using water or oil to rapidly cool the metal. Therefore, if heating any metal, always allow it to cool slowly to avoid changing the hardness of the steel. The SAE numbering designation usually includes four numbers:
The first two numbers indicate the type of alloy which could include several alloy elements.
The last two numbers designate the points of carbon. 1xxx ⫽ plain carbon steels 2xxx ⫽ nickel steels 3xxx ⫽ nickel-chromium steels 4xxx ⫽ molybdenum steels 5xxx ⫽ chromium steels 6xxx ⫽ chromium-vanadium steels 7xxx ⫽ tungsten-chromium steels 9xxx ⫽ silicon-manganese steels
A commonly used alloy for forged crankshafts is SAE 4340. The analysis of this designation is: 4340 ⫽ An alloy that contains 1.82% nickel, 0.5% to 0.8% chromium, and 0.25% molybdenum with 40 points of carbon.
ALUMINUM AND ALUMINUM ALLOYS Aluminum is a lightweight metal that is used in many automotive applications, including suspension components, engine blocks, and cylinder heads. Aluminum is almost always combined with small quantities of other metals to form an alloy, using copper, manganese, zinc, or silicon. Aluminum and aluminum alloys that are mechanical shaped are called wrought alloys and are labeled according to the International Alloy Designation system. The system uses a four-digit number, which identifies the alloying elements, followed by a dash (-) and then a letter identifying the type of heat treatment. This is followed by a number identifying the specific hardness or temper of the finished alloy. A typical example would be 6061-T6. The 6061 is a 6000 series alloy with magnesium and silicon. The “61” further identifies other elements and their percentages. The numbering system for cast aluminum alloy is similar but is designed by standards of the Aluminum Association (AA). SC I E N T I F I C PRI N C I PL E S A N D M A T ERIA L S
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REVIEW QUESTIONS 1. What is kinetic energy?
4. How can a burn test help identify the type of plastic used?
2. How is mechanical advantage used in the braking system?
5. What is the pH of acids and bases?
3. What is the difference between torque and power?
CHAPTER QUIZ 1. All of the following are correct statements about braking except: a. Kinetic energy must be absorbed by the braking system. b. Kinetic energy of a vehicle doubles when the speed doubles. c. The heavier the vehicle, the greater the kinetic energy when moving. d. If the vehicle weight is doubled, the kinetic energy of a moving vehicle is doubled. 2. The brake pedal assembly uses a mechanical lever to ______________. a. Increase the driver’s force on the brake pedal applied to the master cylinder. b. Decrease the distance the brake pedal needs to be depressed by the driver. c. Decrease the driver’s force on the brake pedal applied to the master cylinder. d. Allow for clearance between the brake pedal and the floor when the brakes are applied.
5. An example of a lever and mechanical advantage used on a vehicle is the ______________. a. Radio volume control c. Fuel tank b. Brake pedal d. Battery 6. Two technicians are discussing temperature and heat. Technician A says that temperature is the intensity of the heat source. Technician B says that heat is the amount of heat. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 7. Heat can move or travel by ______________. a. Conduction c. Radiation b. Convection d. All of the above 8. Technician A says that zero degrees Celsius is the freezing temperature of water. Technician B says that 100 degrees Celsius is the boiling temperature of water. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
3. Technician A says that work is being performed if a force is being applied, yet the object does not move. Technician B says that torque is a twisting force that may or may not result in motion. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
9. Technician A says that pure (distilled) water has a pH of 7. Technician B says that the pH of acids is less than 7. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
4. Two technicians are discussing engine horsepower and torque figures. Technician A says that torque is measured on a dynamometer. Technician B says that horsepower is measured on a dynamometer. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
10. Technician A says that the kinetic energy of a vehicle is proportional to its weight. Technician B says that the kinetic energy of a moving vehicle is directly proportional to its speed. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
chapter
14
MATH, CHARTS, AND CALCULATIONS
OBJECTIVES: After studying Chapter 14, the reader will be able to: • Add and subtract decimal numbers. • Read a chart and graph. • Calculate percentages. • Explain how to work with fractions. • Demonstrate how to multiply and divide. • Discuss ratios. • Calculate fuel economy. KEY TERMS: Chart 118 • Decimal point 115 • Diagram 118 • Direct drive 117 • Drive gear 117 • Driven gear 117 • Fractions 116 • Gear reduction 117 • Graph 117 • Overdrive 117 • Percentage 115 • Scientific notation 115 • Variable 117
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DECIMALS Decimals are commonly used by service technicians. The placement of the decimal point indicates the value of the number. The naming of decimals includes tenths, hundredths, thousandths, and higher. Decimals are used to represent fractions of a unit by using a dot called a decimal point to indicate that the number is a decimal.
TENTHS A decimal with one number to the right of the decimal point indicates an accuracy of 1/10 or 0.1. For example, 0.7 is the same as 7/10 and is pronounced “seven tenths” or “zero point seven.” A decimal can also include numbers larger than zero, but has a resolution or accuracy measured in tenths, such as in 14.7.
VALVE CLEARANCE
CAM LOBE HEEL
ADJUSTING SHIM
CAM FOLLOWER
FIGURE 14–1 Valve clearance allows the metal parts to expand and maintain proper operation, both when the engine is cold or at normal operating temperature. Adjustment is achieved by changing the thickness of the adjusting shim.
HUNDREDTH
Decimals with two numbers to the right of the decimal point indicate an accuracy to 1/100 or 0.01. For example, 0.47 is pronounced “forty-seven hundredth” or “zero point four seven.”
THOUSANDTH A decimal with three numbers to the right of the decimal point indicates an accuracy to 1/1000 or 0.001. For example, 0.867 is pronounced “eight hundred sixty-seven thousandth” or “zero point eight six seven.” ADDING AND SUBTRACTING DECIMALS When adding or subtracting decimals, the decimal point has to be aligned. This ensures that the numbers are placed into the correct position of tenth, hundredth, and thousandth. For example: 0.147 ⫹ 0.02 0.167 Notice that the top number is expressed in thousandths and the lower number is expressed in hundredths. The final figure is also shown in thousandths. NOTE: If these numbers were measurements, the first result cannot be more accurate than the least accurate measurement. This means that the final result should be expressed in hundredths instead of thousandths. When subtracting or multiplying decimals, keep the decimal points aligned or use a calculator making certain to include the decimal point.
PERCENTAGE Percentage is the relationship of a value or number out of 100. Using money as an example, three quarters (25 cents each) equals 75 cents ($0.75) or 75% of a dollar ($1.00). Many examples are not that easy, for example, 70 is what percentage of 120? To determine the percentage, divide the first number (70) by the second number (120). 70 120 0.58 To convert this number to a percentage, multiply the number by 100 or move the decimal point two places to the right (58) and then add a percentage symbol to indicate that the number is a percentage (58%).
SCIENTIFIC NOTATION Very large and very small decimal numbers are frequently expressed using scientific notation. Scientific notation is written as a number multiplied by the number of zeros to the right or left of the decimal point. For example, 68,000 could be written as 6.8 ⫻ 104, indicating that the number shown has 3 zeros plus the 8 to the right of the decimal point. Small numbers, such as 0.00068, would use a negative sign beside the number over the 10 to represent that the decimal point needs to be moved toward the left (6.8 ⫻ 10⫺4).
ADDING AND SUBTRACTING Technicians are often required to add or subtract measurements when working on vehicles. For example, adding and subtracting is needed to select shims (thin pieces of steel) for adjusting valve clearance or differential preload measurements. For example, if the valve clearance specification is 0.012 in. and the clearance is actually 0.016 in., and the shim that is in place between the camshaft lobe and the valve bucket is 0.080 in. thick, what size (thickness) of shim needs to be installed to achieve the correct valve clearance? Solution: The shim thickness of 0.080 in. results in a valve clearance of 0.016 in. The specification requires that the shim needs to be thicker to reduce the valve clearance. SEE FIGURE 14–1. To determine the thickness of a shim, the amount of clearance needed to be corrected needs to be calculated. The original clearance is 0.016 in. and the specification is 0.012 in. The difference is determined by subtracting the actual clearance from the specified clearance: 0.016 0.012 0.004 in. The result (0.004 in.) then needs to be added to the thickness of the existing shim to determine the thickness of the replacement shim needed to achieve the correct valve clearance. Existing shim thickness 0.080 in. Additional thickness needed 0.004 in. Thickness of new shim 0.084 in.
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?
FRACTIONS
FREQUENTLY ASKED QUESTION
How Is Metric Fuel Economy Measured? Fractions, such as 1/2, 1/4, or 5/8 are commonly found in specifications for hose inside diameter measurements. A tape measure or machinists rule can be used to measure the fitting or the original part. Sometimes, fractions need to be converted to decimal units if the replacement parts are offered by that measurement method. When comparing fractions to decimal units, think about the number of cents in a dollar. 1/2 dollar ⫽ 50 cents
In the United States fuel economy is expressed in miles per gallon. Outside of the United States, fuel economy is measured in the number of liters of fuel needed to travel 100 kilometers (62 miles), abbreviated L/100 km. This means that as the number increases, the fuel economy decreases. For example: MPG
L/100 km
5
47.0
1/10 (dime) ⫽ 10 cents
10
23.5
1/20 (nickel) ⫽ 5 cents
15
15.7
20
11.8
25
9.4
Quarter ⫽ 25 cents
Other fractions, such as 3/8, 5/8, and 5/16 are harder to determine. If a chart is not available, divide the bottom number, called the denominator into the top number, called the numerator.
30
7.8
3/8 ⫽ 3 divided by 8 ⫽ 0.375
35
6.7
5/8 ⫽ 5 divided by 8 ⫽ 0.625
40
5.9
45
5.2
50
4.7
5/16 ⫽ 5 divided by 16 ⫽ 0.3125
MULTIPLYING AND DIVIDING Multiplying by a service technician is usually done to determine gear ratios and to determine the total of many of the same items. For example, the final overall gear ratio is determined by multiplying the transmission gear ratio by the final drive ratio and is covered later in this chapter. Dividing is commonly done when calculating total resistance of many resistances connected in parallel. In this situation, the value of the resistance is divided by the number of equal resistances. For example, if four bulbs with a resistance of 0.4 ohm were connected in parallel, the total resistance would be just 0.1 ohm (0.4 ⫼ 4 ⫽ 0.1).
In the metric system, the fuel is measured; in the United States, the miles are measured.
Replacing the terms with the actual numbers results in the following: RPM
5668 70 2.41 336 2180 RPM 26 26
FUEL ECONOMY CALCULATOR MATHEMATICAL FORMULAS A formula uses letters to represent values or measurements and indicates how these numbers are to be multiplied, divided, added, or subtracted. To use a formula, the technician needs to replace the letters with the actual number and perform the indicated math functions. For example, a formula used to determine engine speed in revolutions per minute (RPM) and is represented by the following formula: RPM
To calculate fuel economy in miles per gallons, two factors must be known: 1. How far was the vehicle driven. 2. How many gallons of fuel were needed. This calculation requires that the fuel tank be filled two times; first at the start of the test and then at the end of the test distance. For example: STEP 1
Fill the tank until the nozzle clicks off. NOTE: Try to use the same station and pump, if possible, to achieve the most accurate results.
mph gear ratio 336 tire diameter (inches)
This formula is used to determine the speed of the engine compared to the gear ratio and tire size. Sometimes, wheel and tire sizes are changed and knowing this is helpful. To calculate the engine speed, the actual information needs to be placed into the formula.
STEP 2
Drive a reasonable distance. For the example, 220 miles were traveled.
STEP 3
Fill the fuel tank and record the number of gallons used. For this example, exactly 10.0 gallons were needed to refill the tank.
Mph 70 mph Gear ratio 2:41:1 Tire diameter 26 inches
STEP 4
Calculate fuel economy: MPG ⫽ Miles driven divided by the number of gallons used.
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MPG 220 divided by 10.0 22.0 miles per gallon
24 TEETH
24 TEETH
8 TEETH
8 TEETH
DRIVE GEAR DRIVEN GEAR
FIGURE 14–2 The drive gear is attached or is closer to the power source and rotates or drives the driven gear.
DRIVEN GEAR
DRIVE GEAR
FIGURE 14–3 If the driven gear is rotating faster than the drive gear, it is called an overdrive ratio. MAX TORQUE = 153.0
MAX. POWER = 170.9
Direct drive
Gear reduction
Overdrive
DIRECT DRIVE If two meshed gears are the same size and have the same number of teeth, they will turn at the same speed. Since the drive gear turns once for each revolution of the driven gear, the gear ratio is 1:1; this is called a direct drive. When a transmission is in direct drive, the engine and transmission turn at the same speed. GEAR REDUCTION
If one gear drives a second gear that has three times the number of teeth, the smaller drive gear must travel three complete revolutions in order to drive the larger gear through one rotation. SEE FIGURE 14–2. Divide the number of teeth on the driven gear by the number of teeth on the drive gear and you get a 3:1 gear ratio (pronounced three to one). This type of gear arrangement, where driven gear speed is slower than drive gear speed, provides gear reduction. Gear reduction may also be called underdrive as drive speed is less than, or under, driven speed. Both terms mean the same thing and use is a matter of preference. Gear reduction is used for the lower gears in a transmission. First gear in a transmission is called “low” gear because output speed, not gear ratio, is low. Low gears have numerically high gear ratios. That is, a 3:1 gear ratio is a lower gear than those with a 2:1 or 1:1 gear ratio. These three ratios taken in order represent a typical upshift pattern from low gear (3:1), to second gear (2:1), to third gear (1:1).
OVERDRIVE Overdrive is the opposite of a gear reduction condition and occurs when a driven gear turns faster than its drive gear. For the gears shown in FIGURE 14–3, the driven gear turns three times for each turn of the drive gear. The driven gear is said to overdrive the drive gear. For this example, the gear ratio is 0.33:1.
175
150
150
125
125
100
100
75
75
50 20
SAE TORQUE (FT-LBS)
When one gear turns another, the speed that the two gears turn in relation to each other is the gear ratio. Gear ratio is expressed as the number of rotations the drive gear must make in order to rotate the driven gear through one revolution. To obtain a gear ratio, simply divide the number of teeth on the driven gear by the number of teeth on the drive gear. Gear ratios, which are expressed relative to the number one, fall into three categories:
SAE HORSEPOWER
GEAR RATIOS
175
50 30
50 40 RPM (X100)
60
70
FIGURE 14–4 A graph showing horsepower and torque. Notice that the curves cross at 5252 RPM or a little bit to the right of the 50, which is expressed as the graph number multiplied by 100. Example is 52 multiplied by 100 equals 5200 RPM. The torque and horsepower curves cross at 5252 RPM because torque is measured by a dynamometer and then horsepower is calculated using a formula which causes both values to be the same at that one engine speed. Overdrive ratios of 0.65:1 and 0.70:1 are typical of those used in automotive applications. NOTE: Ratios always end in 1 with a colon in between. Therefore, the first number is less than 1 if it is an overdrive ratio and greater than 1 if it is a gear reduction ratio.
GRAPHS, CHARTS, AND DIAGRAMS GRAPH READING
A graph is a visual display of information. Graphs are commonly used in the automotive service industry to illustrate trends or specifications along with time or some other variable. A variable is a measurement of something that changes, such as engine speed or time. A graph has two variables displayed. One variable changes from left to right on the horizontal axis. This is called the X axis. The other variable is displayed on the vertical axis, called the Y axis. A graph is created by making a series of dots at various locations and then connecting the dots with a line. SEE FIGURE 14–4.
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RANGE
FORWARD CLUTCH
FORWARD SPRAG CL. ASSEMBLY
FIRST GEAR
APPLIED
HOLDING
SECOND GEAR APPLIED
APPLIED
HOLDING
THIRD GEAR
APPLIED
HOLDING
GEAR
2–4 BAND
REVERSE OVERRUN INPUT CLUTCH CLUTCH
3–4 CLUTCH
LO-ROLLER CLUTCH
LO-REV. CLUTCH
PARKNEUTRAL HOLDING
OVERDRIVE FOURTH GEAR
APPLIED
APPLIED
APPLIED
FIRST GEAR
APPLIED
APPLIED
HOLDING
SECOND GEAR APPLIED
APPLIED
APPLIED
HOLDING
THIRD GEAR
APPLIED
APPLIED
HOLDING
FIRST GEAR
APPLIED
APPLIED
HOLDING
SECOND GEAR APPLIED
APPLIED
APPLIED
HOLDING
MANUAL 1ST
FIRST GEAR
APPLIED
REVERSE
REVERSE
DRIVE
MANUAL 2ND
APPLIED
HOLDING
APPLIED
HOLDING
APPLIED
HOLDING
HOLDING
APPLIED APPLIED
FIGURE 14–5 A typical chart showing what is applied in what gear in an automatic transmission. INTERPRETING A GRAPH. To interpret a graph, select a point along the horizontal axis (X axis) and then look directly above the point where the line appears. Mark this spot and then look directly to the left along the vertical axis (Y axis) to see what value is represented by the points on the graph.
CHART READING A chart is used to represent data, such as numbers or specifications, along with another variable, such as model or year of vehicle. A chart is very useful for showing many different specifications or other facts in an easy-to-read format. SEE FIGURE 14–5 for an example of a transmission specifications chart, which shows the transmission parts listed along the horizontal axis (X axis) and gear of the automatic transmission along the vertical or Y axis. INTERPRETING A CHART. A chart can look complicated but if studied, it is easy to interpret. Start by looking along the horizontal or vertical axis for the information, such as the range of the transmission down the left column. Then look to the right to find which device is being used to achieve that transmission drive range.
DIAGRAM READING A diagram is a graphic design that explains or shows the arrangement of parts. Diagrams are commonly used in the automotive service industry to show how a component is assembled and in which order the parts are placed together. SEE FIGURE 14–6 for an example. INTERPRETING A DIAGRAM A diagram usually shows the relationship of many parts. Lines are used to show the centerline of the part and the identity of the part is often shown as a number or letter. A separate chart or area of the diagram needs to be looked at to determine the name of the part. Diagrams are most helpful when disassembling or assembling a component, such as a transmission.
FIGURE 14–6 An exploded view showing how the thermostat is placed in the engine.
For best results, use electronic information and print out the diagram so it can be written on and can be thrown away when the repair has been completed. This process also helps prevent getting grease on the pages of a service manual.
REVIEW QUESTIONS 1. What is the formula for determining fuel economy? 2. Why are the torque and horsepower of an engine equal at 5252 RPM? 3. What service operation may require the technician to add and subtract?
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4. What service operation may require the technician to multiply or divide? 5. How is fuel economy expressed in the metric system? 6. What math function is needed to calculate the overall gear ratio if the transmission and differential ratios are both known?
CHAPTER QUIZ 1. Ten of 30 vehicles checked during a safety inspection had at least one tire that was under inflated. This represents what percentage of the vehicles? a. 25% c. 43% b. 33% d. 67% 2. Which of the following shows the relationship of parts? a. Chart c. Diagram b. Graph d. Schematic 3. Add 0.102 in. and 0.080 inch. The answer is ______________. a. 0.182 inch c. 0.0082 inch b. 0.1082 inch d. 0.8200 inch 4. Which is the largest? a. 1/10 b. .25
c. .375 d. 1/50
7. 3/16 is what number in decimal form? a. 0.1875 c. 0.5333 b. 1.875 d. 5.333 8. How is 0.183 pronounced? a. One hundred eighty-three thousandth b. One thousand eighty-three c. Zero dot one hundred and eighty-three hundredths d. One tenth and 83 hundredths 9. Metric fuel economy is measured in what units? a. Miles per gallon b. Miles per kilometer c. Liters per 100 kilometers d. Kilometers per liter 10. Which is the smallest? a. 1/16 b. .25
5. What is 26 out of 87 in percentage? a. 33.5% c. 29.89% b. 11.3% d. 61.0%
c. 3/8 d. .33
6. What number is being represented by the scientific notation 6.28 ⫻ 103? a. 6.28 c. 6,280 b. 628 d. 62,800
S E C T I O N
V
Vehicle Service Information, Identification, and Routine Maintenance 17 Preventative Maintenance and Service Procedures
15 Service Information 16 Vehicle Identification and Emission Ratings
chapter
SERVICE INFORMATION
15 OBJECTIVES: After studying Chapter 15, the reader should be able to: • Discuss the importance of vehicle history. • Retrieve vehicle service information. • Read and interpret service manuals and electronic service information. • Describe the use of the vehicle owner’s manual. KEY TERMS: Julian date 123 • Labor guides 122 • Service information 120 • Technical service bulletin (TSB) 122
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REAL WORLD FIX Owner’s Manual Is the Key to Proper Operation A customer purchased a used Pontiac Vibe and complained to a shop that the cruise control would disengage and had to be reset if driven below 25 mph (40 km/h). The service technician was able to verify that in fact this occurred, but did not know if this feature was normal or not. The technician checked the owner’s manual and discovered that this vehicle was designed to operate this way. Unlike other cruise control systems, those systems on Toyota-based vehicles are designed to shut off below 25 mph, requiring the driver to reset the desired speed. The customer was informed that nothing could be done to correct this concern and the technician also learned something. Vehicles that use the Toyota cruise control system include all Toyotas, plus Lexus, Pontiac Vibe, and Chevrolet Prism.
FIGURE 15–1 The owner’s manual has a lot of information pertaining to the operation as well as the maintenance and resetting procedures that technicians often need.
VEHICLE SERVICE HISTORY RECORDS Whenever service work is performed, a record of what was done is usually kept on file by the shop or service department for a number of years. The wise service technician will check the vehicle service history if working on a vehicle with an unusual problem. Often, a previous repair may indicate the reason for the current problem or it could be related to the same circuit or components. For example, a collision could have caused hidden damage that can affect the operation of the vehicle. Knowing that a collision had been recently repaired may be helpful to the technician.
OWNER’S MANUALS It has been said by many automotive professional technicians and service advisors that the owner’s manual is not read by many vehicle owners. Most owner’s manuals contain all or most of the following information.
HINT: Some vehicle manufacturers offer owner’s manuals on their website for a free download.
Grease and oil specifications
Capacities for engine oil, transmission fluid, coolant and differential fluid
SERVICE MANUALS Factory and aftermarket service manuals, also called shop manuals, contain specifications and service procedures. While factory service manuals cover just one year and one or more models of the same vehicle, most aftermarket service manuals cover multiple years and/ or models in one manual. Included in most service manuals are the following:
Capacities and recommended specifications for all fluids
Specifications including engine and routine maintenance items
Testing procedures
Service procedures including the use of special tools when needed
Component location information
1. How to reset the maintenance reminder light 2. Specifications, including viscosity of oil needed and number of quarts (liters) 3. Tire pressures and standard as well as optional tire sizes 4. Maintenance schedule for all fluids, including coolant, brake fluid, automatic transmission fluid, and differential fluid 5. How to program the remote control as well as the power windows and door locks 6. How to reset the tire pressure monitoring system after a tire rotation
SEE FIGURE 15–1
LUBRICATION GUIDES Lubrication guides, such as those published by Chek-Chart and Chilton, include all specifications for lubrication-related service including:
While some factory service manuals are printed in one volume, most factory service information is printed in several volumes due to the amount and depth of information presented. The typical factory service manual is divided into sections.
GENERAL INFORMATION
Warnings and cautions
Vehicle identification numbers on engine, transmission/ transaxle, and body parts
Lock cylinder coding
Fastener information
Decimal and metric equivalents Abbreviations and standard nomenclature used Service parts identification label and process code information
Hoisting location
Lubrication points
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General information includes top-
ics such as:
TECH TIP
TECH TIP Exploded Views
Print It Out
Exploded views of components such as engines and transmissions are available in shop manuals and electronic service information, as well as in parts and labor time guides. These views, showing all of the parts as if the assembly was blown apart, give the service technician a clear view of the various parts and their relationship to other parts in the assembly.
It is often a benefit to have the written instructions or schematics (wiring diagrams) at the vehicle while diagnosing or performing a repair. One advantage of a hard copy service manual is that it can be taken to the vehicle and used as needed. However, dirty hands can often cause pages to become unreadable. The advantage of electronic format service information is that the material can be printed out and taken to the vehicle for easy access. This also allows the service technician to write or draw on the printed copy, which can be a big help when performing tests such as electrical system measurements. These notes can then be used to document the test results on the work order.
MAINTENANCE
AND
LUBRICATION
INFORMATION
Maintenance and lubrication information includes topics such as:
Schedule for “normal” as well as “severe” usage time and mileage charts
Specified oil and other lubricant specifications
Chassis lubrication points
Tire rotation methods
Repair procedures (wire repair, connectors, and terminals)
Periodic vehicle inspection services (items to check and time/ mileage intervals)
Power distribution
Ground distribution
Component location views
Harness routing views
Individual electrical circuits, including circuit operation and schematics
Maintenance item part numbers, such as oil and air filter numbers, and specifications, such as oil capacity and tire pressures
ENGINES
Engine electrical diagnosis (battery, charging, cranking, ignition, and wiring)
Engine mechanical diagnosis
Specific engine information for each engine that may be used in the vehicle(s) covered by the service manual, including:
HEATING, VENTILATION, AND AIR CONDITIONING
Engine identification
On-vehicle service procedures
Description of the engine and the operation of the lubrication system
Exploded views showing all parts of the engine
Disassembly procedures
Inspection procedures and specifications of the parts and subsystems
Heater system
General description
Heater control assembly
Diagnosis, including heater electrical wiring and vacuum system
Blower motor and fan assembly diagnosis and servicing procedures
Air distribution values
Fastener torque specifications
Air-conditioning system
Assembly procedures
General description and system components
Torque specifications for all fasteners, including the torque sequence
Air-conditioning system diagnosis, including leak detection
Air-conditioning and heater function tests
Air-conditioning service procedures
AUTOMATIC TRANSMISSION/TRANSAXLE
General information (identification and specifications)
Diagnosis procedures, including preliminary checks and fluid level procedures
Refrigerant recovery, recycling, adding oil, evacuating procedures, and charging procedures
Troubleshooting guide
General service, including leak detection and correction
Cooler flushing procedures
Unit removal procedures
Unit disassembly procedures and precautions
Unit assembly procedures and torque specifications
ELECTRICAL SYSTEMS
ENGINE PERFORMANCE (DRIVEABILITY AND EMISSIONS)
Vehicle emission control information (VECI) label, visual/ physical underhood inspection
On-board diagnostic system
Scan tool values
Wiring harness service Symptom charts Diagnostic trouble code (DTC) information
Symbols used
Troubleshooting procedures
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TECH TIP Look for Severe Service Times Many time guides provide additional time for vehicles that may be excessively rusted due to climate conditions or have been subjected to abuse. Be sure to quote the higher rate if any of these conditions are present on the customer’s vehicle.
ADVANTAGES OF HARD COPY VERSUS ELECTRONIC SERVICE INFORMATION All forms of service information have some advantages, including: Hard Copy • Easy to use—no hardware or expensive computers needed • Can be taken to the vehicle for reference • Can view several pages easily for reference
FIGURE 15–2 Some technical service bulletins also include the designated flat-rate time when specifying a repair procedure.
Electronic Service Information • Information can be printed out and taken to the vehicle • Has a search function for information • Internet or network access allows use at several locations in the shop
DISADVANTGES OF HARD COPY VERSUS ELECTRONIC SERVICE INFORMATION All forms of service information have some disadvantages, including:
ELECTRONIC SERVICE INFORMATION There are many programs available that will provide electronic service information for the automotive industry. Sometimes the vehicle makers make information available on CDs or DVDs, but mostly it is available online. Most electronic service information has technical service bulletins (TSBs), wiring diagrams and a main menu that includes the major components of the vehicle as a starting point. SEE FIGURE 15–3. ALLDATA and Mitchell On-Demand are commonly used software programs that include service information for many vehicles. Service information and testing procedures should be closely followed including any symptom charts or flow charts. A sample of a symptom information chart is shown CHART 15–1.
Hard Copy
Electronic Service Information
HOME SCREEN The Home screen is the first screen displayed when you start. It displays buttons that represent the major sections of the program. Access to the Home screen is available from anywhere within the program by clicking the Home button on the toolbar.
• Can be lost or left in the vehicle
• Requires a computer and printer
TOOLBARS
• Cost is high for each manual
• Internet or network access can be a challenge
• Can get dirty and unreadable
• Cost can be high
LABOR GUIDE MANUALS Labor guides, also called flat-rate manuals, list vehicle service procedures and the time it should take an average technician to complete the task. This flat-rate time is then the basis for estimates and pay for technicians. Some manuals also include a parts list, including the price of the part to help service advisors create complete estimates for both labor and parts. These manuals are usually called “parts and time guides.” Some guides include labor time only. SEE FIGURE 15–2.
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A main toolbar is displayed on most screens, providing quick access to certain functions. This toolbar varies somewhat, depending upon what information is being accessed.
ELECTRONIC SERVICE INFORMATION Electronic service information is available mostly by subscription and provides access to an Internet site where service manual–type information is available. Most vehicle manufacturers also offer electronic service information to their dealers and to most schools and colleges that offer corporate training programs. TECHNICAL SERVICE BULLETINS Technical service bulletins, often abbreviated TSBs, are issued by the vehicle manufacturer to notify service technicians of a problem and include the necessary corrective action. Technical service bulletins are designed for dealership technicians but are republished by aftermarket companies and made available along with other service information to shops and vehicle repair facilities.
INTERNET The Internet has opened the field for information exchange and access to technical advice. One of the most useful websites is the International Automotive Technician’s network at www.iatn.net. This is a free site but service technicians need to register to join. For a small monthly sponsor fee, the shop or service
technician can gain access to the archives, which include thousands of successful repairs in the searchable database.
RECALLS AND CAMPAIGNS
A recall or campaign is issued by a vehicle manufacturer and a notice is sent to all owners in the event of a safety- or emission-related fault or concern. While these faults may be repaired by independent shops, it is generally handled by a local dealer. Items that have created recalls in the past have included potential fuel system leakage problems, exhaust leakage, or electrical malfunctions that could cause a possible fire or the engine to stall. Unlike technical service bulletins whose cost is only covered when the vehicle is within the warranty period, a recall or campaign is always done at no cost to the vehicle owner.
?
FREQUENTLY ASKED QUESTION
What Is the Julian Date?
FIGURE 15–3 A main menu showing the major systems of the vehicle. Clicking on one of these major topics opens up another menu showing more detailed information.
The Julian date (abbreviated JD) is the number of the day of the year. January 1 is day 001. The Julian date is named for Julius Caesar, who developed the current calendar. The Julian date is often mentioned in technical service bulletin where changes need to be made to certain component if the date of manufactured falls within the specified Julian dates.
POSSIBLE CAUSE
REASON
Throttle-position (TP) sensor
• The TP sensor should be within the specified range at idle. If too high or too low, the computer may not provide a strong enough extra pulse to prevent a hesitation. • An open or short in the TP sensor can result in hesitation because the computer would not be receiving correct information regarding the position of the throttle.
Throttle-plate deposit buildup
An airflow restriction at the throttle plates creates not only less air reaching the engine but also swirling air due to the deposits. This swirling or uneven airflow can cause an uneven air-fuel mixture being supplied to the engine, causing poor idle quality and a sag or hesitation during acceleration.
Manifold absolute pressure (MAP) sensor fault
The MAP sensor detects changes in engine load and signals to the computer to increase the amount of fuel needed for proper operation. Check the vacuum hose and the sensor itself for proper operation.
Check the throttle linkage for binding
A kinked throttle cable or cruise (speed) control cable can cause the accelerator pedal to bind.
Contaminated fuel
Fuel contaminated with excessive amounts of alcohol or water can cause a hesitation or sag during acceleration. HINT: To easily check for the presence of alcohol in gasoline, simply get a sample of the fuel and place it in a clean container. Add some water and shake. If no alcohol is in the gasoline, the water will settle to the bottom and be clear. If there is alcohol in the gasoline, the alcohol will absorb the water. The alcohol-water combination will settle to the bottom of the container, but will be cloudy rather than clear.
Clogged, shorted, or leaking fuel injectors
Any injector problem that results in less than an ideal amount of fuel being delivered to the cylinders can result in a hesitation, a sag, or stumble during acceleration.
Spark plugs or spark plug wires
Any fault in the ignition system such as a defective spark plug wire or cracked spark plug can cause hesitation, a sag, or stumble during acceleration. At higher engine speeds, a defective spark plug wire is not as noticeable as it is at lower speeds, especially in vehicles equipped with a V-8 engine.
EGR valve operation
Hesitation, a sag, or stumble can occur if the EGR valve opens too soon or is stuck partially open.
False air
A loose or cracked intake hose between the mass airflow (MAF) sensor and the throttle plate can be the cause of hesitation.
CHART 15–1 A chart showing symptoms for hesitation while accelerating. These charts help the technician diagnose faults that do not set a diagnostic trouble code (DTC).
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TECH TIP Use a Bluetooth Hands-Free Telephone When talking to a hotline service provider, it is wise to be looking at the vehicle during the call to be able to provide information about the vehicle and perform the suggested tests. This makes the job of troubleshooting easier and faster for both the technician and the service provider, resulting in shorter length calls. Using a Bluetooth hands-free telephone should help shorten the length of calls, which means the cost will be less for the help service.
FIGURE 15–4 Whenever calling a hot line service be sure that you have all of the vehicle information ready and are prepared to give answers regarding voltage readings or scan tool data when talking to the vehicle specialist.
HOTLINE SERVICES A hotline service provider is a subscription-based helpline to assist service technicians solve technical problems. While services vary, most charge a monthly fee for a certain amount of time each month to talk to an experienced service technician who has a large amount of resource materials available for reference. Often, the technician hired by the hotline services specializes in one vehicle make and is familiar with many of the pattern failures that are seen by other technicians in the field. Hotline services are an efficient way to get information on an as-needed basis. Some examples of hotline automotive service providers include:
SPECIALITY REPAIR MANUALS Examples of specialty repair manuals include unit repair for assembled components, such as automatic transmission/transaxle, manual transmission/transaxle, differentials, and engines. Some specialty repair manuals cover older or antique vehicles, which may include unit repair sections.
AFTERMARKET SUPPLIES GUIDES AND CATALOGS Aftermarket supplies guides and catalogs are usually free and often include expanded views of assembled parts along with helpful hints and advice. Sometimes the only place where this information is available is at trade shows associated with automotive training conferences and expos. Go to the following websites for examples of training conferences with trade shows.
Identifix
Autohotlineusa
Taylor Automotive Tech-Line
www.CARSevent.com
Aspire
www.avtechexpo.com
SEE FIGURE 15–4
www.visionkc.com (Vision Expo)
REVIEW QUESTIONS 1. What is included in the vehicle owner’s manual that could be helpful for a service technician?
4. Explain how flat-rate and parts guides are useful to customers.
2. Lubrication service guides include what type of information?
6. Describe how hotline services and Internet sites assist service technicians.
3. Explain why factory service manuals or factory electronic service information are the most detailed of all service information.
5. List additional types of service manuals that are available.
CHAPTER QUIZ 1. What type of information is commonly included in the owner’s manual that would be a benefit to service technicians? a. Maintenance reminder light reset procedures b. Tire pressure monitoring system reset procedures c. Maintenance items specifications d. All of the above
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2. Two technicians are discussing the need for the history of the vehicle. Technician A says that an accident could cause faults due to hidden damage. Technician B says that some faults could be related to a previous repair. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
3. The viscosity of engine oil is found where? a. Owner’s manual b. Factory service manual or service information c. Lubrication guide d. All of the above
8. Hotline services are ______________. a. Free b. Available for a service fee c. Available on CD or DVD format d. Accessed by the Internet
4. Wiring diagrams are usually found where? a. Owner’s manuals c. Unit repair manuals b. Factory service manuals d. Lubrication guides
9. Aftermarket parts catalogs can be a useful source of information and they are usually ______________. a. Free b. Available by paid subscription c. Available on CD or DVD d. Available for a fee on a secured Internet site
5. What type of manual includes time needed to perform service procedures? a. Flat-rate manuals c. Factory service manuals b. Owner’s manuals d. Parts guide 6. Component location can be found in ______________. a. Factory service manuals b. Owner’s manuals c. Component location manuals d. Both a and c
10. Which type of manual or service information includes the flatrate time and the cost of parts? a. Parts and time guides b. Factory service manuals c. Component location guides d. Free Internet sites
7. Aftermarket service information is available in what format? a. Manuals c. Internet b. CDs or DVDs d. All of the above
chapter
16
VEHICLE IDENTIFICATION AND EMISSION RATINGS
OBJECTIVES: After studying Chapter 16, the reader should be able to: • Identify a vehicle. • Interpret vehicle identification numbers and placard information. • Interpret vehicle emissions and emission control information. • Read and interpret casting numbers. • Locate calibration codes. KEY TERMS: Bin number 127 • Calendar year (CY) 126 • Calibration codes 128 • California Air Resources Board (CARB) 127 • Casting numbers 128 • Country of origin 126 • Environmental Protection Agency (EPA) 127 • Gross axle weight rating (GAWR) 126 • Gross vehicle weight rating (GVWR) 126 • Model year (MY) 126 • Tier 1 127 • Tier 2 127 • Vehicle emissions control information (VECI) 126 • Vehicle identification number (VIN) 126
PARTS OF A VEHICLE The names of the parts of a vehicle are based on the location and purpose of the component.
LEFT SIDE OF THE VEHICLE—RIGHT SIDE OF THE VEHICLE Both of these terms refer to the left and right as if the driver is sitting behind the steering wheel. Therefore, the left side (including components under the hood) is on the driver’s side.
FRONT AND REAR The proper term for the back portion of any vehicle is rear (for example, left rear tire).
FRONT-WHEEL DRIVE VERSUS REAR-WHEEL DRIVE Front-wheel drive (FWD) means that the front wheels are being driven by the engine, as well as turned by the steering wheel. Rearwheel drive (RWD) means that the rear wheels are driven by the engine. If the engine is in the front, it can be either front- or rear-wheel drive. In many cases, a front engine vehicle can also drive all four wheels called four-wheel drive (4WD) or all-wheel drive (AWD). If the engine is located at the rear of the vehicle, it can be rear-wheel drive or four-wheel (AWD) drive.
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FIGURE 16–1 Typical vehicle identification number (VIN) as viewed through the windshield.
FIGURE 16–2 A VECI label on a 2008 Ford. A ⫽ 1980/2010
L ⫽ 1990/2020
Y ⫽ 2000/2030
B ⫽ 1981/2011
M ⫽ 1991/2021
1 ⫽ 2001/2031
N ⫽ 1992/2022
2 ⫽ 2002/2032
1 ⫽ United States
9 ⫽ Brazil
U ⫽ Romania
C ⫽ 1982/2012
2 ⫽ Canada
J ⫽ Japan
V ⫽ France
D ⫽ 1983/2013
P ⫽ 1993/2023
3 ⫽ 2003/2033
3 ⫽ Mexico
K ⫽ Korea
W ⫽ Germany
E ⫽ 1984/2014
R ⫽ 1994/2024
4 ⫽ 2004/2034
4 ⫽ United States
L ⫽ China
X ⫽ Russia
F ⫽ 1985/2015
S ⫽ 1995/2025
5 ⫽ 2005/2035
T ⫽ 1996/2026
6 ⫽ 2006/2036
5 ⫽ United States
R ⫽ Taiwan
Y ⫽ Sweden
G ⫽ 1986/2016
6 ⫽ Australia
S ⫽ England
Z ⫽ Italy
H ⫽ 1987/2017
V ⫽ 1997/2027
7 ⫽ 2007/2037
8 ⫽ Argentina
T ⫽ Czechoslovakia
J ⫽ 1988/2018
W ⫽ 1998/2028
8 ⫽ 2008/2038
K ⫽ 1989/2019
X ⫽ 1999/2029
9 ⫽ 2009/2039
CHART 16–1
CHART 16–2 VIN Year Chart (The Pattern Repeats Every 30 Years)
VEHICLE IDENTIFICATION All service work requires that the vehicle, including the engine and accessories, be properly identified. The most common identification is the make, model, and year of the vehicle. Make: e.g., Chevrolet Model: e.g., Impala Year: e.g., 2007 The year of the vehicle is often difficult to determine exactly. A model may be introduced as the next year’s model as soon as January of the previous year. Typically, a new model year (abbreviated MY) starts in September or October of the year prior to the actual new year, but not always. This is why the vehicle identification number, usually abbreviated VIN, is so important. SEE FIGURE 16–1. Since 1981, all vehicle manufacturers have used a VIN that is 17 characters long. Although every vehicle manufacturer assigns various letters or numbers within these 17 characters, there are some constants, including:
The first number or letter designates the country of origin. SEE CHART 16–1.
The model of the vehicle is commonly the fourth and/or fifth character.
The eighth character is often the engine code. (Some engines cannot be determined by the VIN number.) The tenth character represents the calendar year (abbreviated CY) on all vehicles. SEE CHART 16–2.
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VEHICLE SAFETY CERTIFICATION LABEL A vehicle safety certification label is attached to the left side pillar post on the rearward-facing section of the left front door. This label indicates the month and year of manufacture as well as the gross vehicle weight rating (GVWR), the gross axle weight rating (GAWR), and the vehicle identification number (VIN).
VECI LABEL The vehicle emissions control information (VECI) label under the hood of the vehicle shows informative settings and emission hose routing information. SEE FIGURE 16–2. The VECI label (sticker) can be located on the bottom side of the hood, the radiator fan shroud, the radiator core support, or the strut towers. The VECI label usually includes the following information.
Engine identification
Emissions standard that the vehicle meets
Vacuum hose routing diagram
Base ignition timing (if adjustable)
Spark plug type and gap
Valve lash
Emission calibration code
ZEV—Zero-Emission Vehicle. A California standard prohibiting any tailpipe emissions. The ZEV category is largely restricted to electric vehicles and hydrogen-fueled vehicles. In these cases, any emissions that are created are produced at another site, such as a power plant or hydrogen reforming center, unless such sites run on renewable energy.
NOTE: A battery-powered electric vehicle charged from the power grid will still be up to 10 times cleaner than even the cleanest gasoline vehicles over their respective lifetimes. The current California ZEV regulation allows manufacturers a choice of two options for meeting the ZEV requirements.
FIGURE 16–3 The underhood decal showing that this Lexus RX-330 meets both national (Tier 2; BIN 5) and California LEV-II (ULEV) regulation standards.
EMISSION STANDARDS IN THE UNITED STATES In the United States, emissions standards are managed by the Environmental Protection Agency (EPA) as well as some U.S. state governments. Some of the strictest standards in the world are formulated in California by the California Air Resources Board (CARB).
TIER 1 AND TIER 2
Federal emission standards are set by the Clean Air Act Amendments (CAAA) of 1990 grouped by tier. All vehicles sold in the United States must meet Tier 1 standards that went into effect in 1994 and are the least stringent. Additional Tier 2 standards have been optional since 2001, and were completely adopted in 2009. The current Tier 1 standards are different between automobiles and light trucks (SUVs, pickup trucks, and minivans), but Tier 2 standards are the same for both types. There are several ratings that can be given to vehicles, and a certain percentage of a manufacturer’s vehicles must meet different levels in order for the company to sell its products in affected regions. Beyond Tier 1, and in order by stringency, are the following levels.
TLEV—Transitional Low-Emission Vehicle. More stringent for HC than Tier 1.
LEV—(also known as LEV I)—Low-Emission Vehicle. An intermediate California standard about twice as stringent as Tier 1 for HC and NOX.
ULEV—(also known as ULEV I). Ultra-Low-Emission Vehicle. A stronger California standard emphasizing very low HC emissions. ULEV II—Ultra-Low-Emission Vehicle. A cleaner-thanaverage vehicle certified under the Phase II LEV standard. Hydrocarbon and carbon monoxide emissions levels are nearly 50% lower than those of a LEV II-certified vehicle. SEE FIGURE 16–3. SULEV—Super-Ultra-Low-Emission Vehicle. A California standard even tighter than ULEV, including much lower HC and NOX emissions; roughly equivalent to Tier 2 Bin 2 vehicles.
1. Vehicle manufacturers can meet the ZEV obligations by meeting standards that are similar to the ZEV rule as it existed in 2001. This means using a formula allowing a vehicle mix of 2% pure ZEVs, 2% AT-PZEVs (vehicles earning advanced technology partial ZEV credits), and 6% PZEVs (extremely clean conventional vehicles). The ZEV obligation is based on the number of passenger cars and small trucks a manufacturer sells in California. 2. Manufacturers may also choose a new alternative ZEV compliance strategy of meeting part of the ZEV requirement by producing the sales-weighted market share of approximately 250 fuel-cell vehicles. The remainder of the ZEV requirements could be achieved by producing 4% AT-PZEVs and 6% PZEVs. The required number of fuel-cell vehicles will increase to 2,500 from 2009 to 2011, 25,000 from 2012 through 2020, and 50,000 from 2015 through 2017. Manufacturers can substitute battery electric vehicles for up to 50% of the fuel-cell vehicle requirements. PZEV—Partial-Zero-Emission Vehicle. Compliant with the SULEV standard; additionally has near-zero evaporative emissions and a 15-year/150,000-mile warranty on its emission control equipment. Tier 2 standards are even more stringent. Tier 2 variations are appended with “II,” such as LEV II or SULEV II. Other categories have also been created.
ILEV—Inherently Low-Emission Vehicle.
AT-PZEV—Advanced Technology Partial-Zero-Emission Vehicle. If a vehicle meets the PZEV standards and is using high-technology features, such as an electric motor or highpressure gaseous fuel tanks for compressed natural gas, it qualifies as an AT-PZEV. Hybrid electric vehicles such as the Toyota Prius can qualify, as can internal combustion engine vehicles that run on natural gas (CNG), such as the Honda Civic GX. These vehicles are classified as “partial” ZEV because they receive partial credit for the number of ZEV vehicles that automakers would otherwise be required to sell in California.
NLEV—National Low-Emission Vehicle. All vehicles nationwide must meet this standard, which started in 2001. SEE CHARTS 16–3 AND 16–4.
FEDERAL EPA BIN NUMBER
The higher the tier number, the newer the regulation; the lower the bin number, the cleaner the vehicle. The 2004 Toyota Prius is a very clean Bin 3, while the Hummer H2 is a dirty Bin 11. Examples include:
Tier 1: The former federal standard; carried over to model year 2004 for those vehicles not yet subject to the phase-in.
Tier 2, Bin 1: The cleanest federal Tier 2 standard; a zeroemission vehicle (ZEV).
Tier 2, Bins 4–2: Cleaner than the average standard.
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NMOG GRAMS (MILE)
CO GRAMS (MILE)
NOX GRAMS (MILE)
CERTIFICATION LEVEL
NMOG (g/ml)
CO (g/ml)
NOX (g/ml)
Bin 1
0.0
0.0
0.0
LEV I (Cars)
TLEV
0.125 (0.156)
3.4 (4.2)
0.4 (0.6)
Bin 2
0.010
2.1
0.02
LEV
0.075 (0.090)
3.4 (4.2)
0.2 (0.3)
Bin 3
0.055
2.1
0.03
ULEV
0.040 (0.055)
1.7 (2.1)
0.2 (0.3)
Bin 4
0.070
2.1
0.04
LEV
0.075 (0.090)
3.4 (4.2)
0.05 (0.07)
Bin 5
0.090
4.2
0.07
ULEV
0.040 (0.055)
1.7 (2.1)
0.05 (0.07)
Bin 6
0.090
4.2
0.10
SULEV
⫺(0.010)
⫺(1.0)
⫺(0.02)
Bin 7
0.090
4.2
0.15
Bin 8a
0.125
4.2
0.20
Bin 8b
0.156
4.2
0.20
Bin 9a
0.090
4.2
0.30
Bin 9b
0.130
4.2
0.30
Bin 9c
0.180
4.2
0.30
Bin 10a
0.156
4.2
0.60
Bin 10b
0.230
6.4
0.60
Bin 10c
0.230
6.4
0.60
Bin 11
0.230
7.3
0.90
LEV II (Cars and Trucks less than 8,500 lbs) CHART 16–3
LEV Standard Categories NOTE: Numbers in parentheses are 100,000-mile standards for LEV I, and 120,000-mile standards for LEV II. NMOG means non-methane organic gases, which includes alcohol. CO means carbon monoxide. NOX means oxides of nitrogen. Data compiled from California Environmental Protection Agency—Air Resource Board (CARB) documents.
CERTIFICATION LEVEL
NMOG (g/ml)
CO (g/ml)
NOX (g/ml)
LEV II
0.090
4.2
0.07
ULEV II
0.055
2.1
0.07
SULEV II
0.010
1.0
0.02
CHART 16–4 California LEV II 120,000-Mile Tailpipe Emissions Limits NOTE: Numbers in parentheses are 100,000-mile standards for LEV I, and 120,000-mile standards for LEV II. NMOG means nonmethane organic gases, which includes alcohol. CO means carbon monoxide. NOX means oxides of nitrogen. The specification is in grams per mile (g/ml). Data compiled from California Environmental Protection Agency—Air Resources Board (CARB) documents.
Tier 2, Bin 5: “Average” of new Tier 2 standards, roughly equivalent to a LEV II vehicle. Tier 2, Bins 6–9: Not as clean as the average requirement for a Tier 2 vehicle. Tier 2, Bin 10: Least-clean Tier 2 bin applicable to passenger vehicles. SEE CHARTS 16–5 AND 16–6.
CALIBRATION CODES Calibration codes are usually located on powertrain control modules (PCMs) or other controllers. Some calibration codes are only accessible with a scan tool. Whenever diagnosing an engine operating fault, it is often necessary to know the calibration code to be sure that the vehicle is the subject of a technical service bulletin or other service procedure. SEE FIGURE 16–4.
CASTING NUMBERS Whenever an engine part such as a block is cast, a number is put into the mold to identify the casting. SEE FIGURE 16–5. These casting numbers can be used to check dimensions such
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CHART 16–5 EPA Tier 2—120,000-Mile Tailpipe Emission Limits NOTE: The bin number is determined by the type and weight of the vehicle. The highest bin allowed for vehicles built after January 1, 2007, is Bin 8. Data compiled from the Environmental Protection Agency (EPA).
U.S. EPA VEHICLE INFORMATION PROGRAM (THE HIGHER THE SCORE, THE LOWER THE EMISSIONS) SELECTED EMISSIONS STANDARDS
SCORE
Bin 1 and ZEV
10
PZEV
9.5
Bin 2
9
Bin 3
8
Bin 4
7
Bin 5 and LEV II cars
6
Bin 6
5
Bin 7
4
Bin 8
3
Bin 9a and LEV I cars
2
Bin 9b
2
Bin 10a
1
Bin 10b and Tier 1 cars
1
Bin 11
0
CHART 16–6 Air Pollution Score Courtesy of the Environmental Protection Agency (EPA).
as the cubic inch displacement and other information. Sometimes changes are made to the mold, yet the casting number is not changed. Most often the casting number is the best piece of identifying information that the service technician can use for identifying an engine.
FIGURE 16–5 Engine block identification number cast into the block is used for identification. FIGURE 16–4 A typical computer calibration sticker on the case of the controller. The information on the sticker is often needed when ordering parts or a replacement controller.
REVIEW QUESTIONS 1. From what position are the terms left and right determined?
3. What information is included on the VECI label under the hood?
2. What are the major pieces of information that are included in the vehicle identification number (VIN)?
4. What does Tier 2 Bin 5 mean?
CHAPTER QUIZ 1. The passenger side is called the ________. a. Right side b. Left side c. Either right or left side, depending on how the vehicle is viewed d. Both a and b
7. The vehicle safety certification label includes all except ________. a. VIN b. GVWR c. Tire pressure recommendation d. GAWR
2. A vehicle with the engine in the front can be ________. a. Front-wheel drive c. Four-wheel drive b. Rear-wheel drive d. All of the above
8. What are the characters that are embedded in most engine blocks and are used for identification? a. VIN c. Bin number b. Calibration codes d. Casting number
3. The vehicle identification number (VIN) is how many characters long? a. 10 c. 17 b. 12 d. 21 4. The tenth character represents the year of the vehicle. If the tenth character is a “Y,” what year is the vehicle? a. 1998 c. 2002 b. 2000 d. 2004 5. The first character of the vehicle identification number is the country of origin. Where was the vehicle built that has a “5” as the first character? a. United States c. Mexico b. Canada d. Japan
9. If the first character of the VIN is an “S,” where was the vehicle made? a. United States c. Canada b. Mexico d. England 10. Technician A says that the lower the bin number is, the cleaner. Technician B says that SULEV has cleaner standards than ULEV. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
6. The VECI label includes all except ________. a. Engine identification b. Horsepower and torque rating of the engine c. Spark plug type and gap d. Valve lash
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chapter
PREVENTATIVE MAINTENANCE AND SERVICE PROCEDURES
17
OBJECTIVES: After studying Chapter 17, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “A” (General Engine Diagnosis) and content area “D” (Lubrication and Cooling Systems Diagnosis and Repair). • Perform routine fluid and service checks. • Explain how to rotate tires. • Describe how to install wheels and tighten lug nuts using a torque wrench and the proper sequence. • Describe chassis system lubrication and under-vehicle inspection. KEY TERMS: Air filter 132 • Alemite fittings 143 • Algorithm 135 • American Petroleum Institute (API) 144 • American Society for Testing Materials (ASTM) 143 • Automatic transmission fluid (ATF) 138 • Brake fluid 133 • Cabin filter 132 • Dipstick 134 • DOT 3 133 • DOT 4 133 • DOT 5 133 • DOT 5.1 134 • National Lubricating Grease Institute (NLGI) 143 • Penetration test 143 • Polyglycol 133 • Preventative maintenance (PM) 130 • Serpentine (Poly V) 139 • Silicone brake fluid 133 • Synchromesh transmission fluid (STF) 144 • Zerk fittings 143
PREVENTATIVE MAINTENANCE
GETTING READY FOR SERVICE PRE-SERVICE INSPECTION
PURPOSE
Preventative maintenance (PM) means periodic service work performed on a vehicle that will help keep it functioning correctly for a long time. All vehicle manufacturers publish a list of service work to be performed on a regular basis. Preventative maintenance is also called routine maintenance because it is usually performed on a set scheduled routine. The interval specified for preventative maintenance is often expressed in time and miles (km) such as:
Every six months (could be longer for many vehicles)
Every 5,000 to 10,000 miles (8,000 to 16,000 km) depending on the vehicle and how it is being operated
Either of the above, whichever occurs first
Prior to any service work, it is wise to check the vehicle for damage and document the work order if any damage is found. In most dealerships and shops, this is the responsibility of the following personnel.
Service adviser (service writer) or
Shop foreman or
Shop owner
The designated person should check the vehicle for the following: 1. Body damage 2. Missing wheel covers 3. Glass damage such as a cracked windshield 4. Any faults in the paint or trim 5. Valid license plates
ITEMS REQUIRING MAINTENANCE
The items or systems
that require routine maintenance include: 1. Engine oil and oil filter replacement 2. Air and cabin filter replacement 3. Tire inflation pressure check, inspection, and rotation 4. Brake and suspension system inspection 5. Underhood inspection and fluid checks
PROTECT THE VEHICLE Before most service work is done, protect the inside of the vehicle by using commercially available plastic or paper protective coverings for the following areas.
Seats
Floor
Steering wheel
SEE FIGURE 17–1
6. Under-vehicle inspection and fluid checks 7. Air-conditioning system inspection and service 8. Safety inspection, such as all lights and windshield wiper blades 9. Routine cleaning of vehicle both inside and out
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PROTECT THE TECHNICIAN
Before starting routine preventative maintenance on a vehicle be sure to perform the following: 1. Open the hood (engine compartment cover). Often the struts that hold a hood open are weak or defective. Therefore, before
FIGURE 17–2 An exhaust system hose should be connected to the tailpipe(s) whenever the engine is being run indoors.
TECH TIP Do No Harm As stated in the Hippocratic oath, a doctor agrees first to do no harm to the patient during treatment. Service technicians should also try to do no harm to the vehicle while it is being serviced. Always ask, “Am I going to do any harm if I do this?” before you do it.
FIGURE 17–1 Before service begins, be sure to cover the seats, floor, and steering wheel with protective coverings. starting to work under the hood, always make sure that the hood is securely held open. 2. Connect an exhaust system hose to the tailpipe(s) before work is started that will involve operating the engine. SEE FIGURE 17–2. 3. Wear personal protective equipment (PPE) including: Safety glasses Hearing protection if around air tools or other loud noises Gloves if handling hot objects or chemicals such as used engine oil
9. Parking brake operation 10. Exhaust system for excessive noise or leaks
4. On hybrid vehicles, make sure that the technician has possession of the key transmitter and that the vehicle is not in the ready mode before starting any inspection or service procedures.
SAFETY INSPECTION A safety inspection is usually recommended to be performed anytime the vehicle is in the shop for service or repair. These inspections should include all of the following: 1. Exterior lights, including: a. Headlights (high and low beam) b. Tail lights c. Turn signals d. License plate light e. Parking lights 2. Horn
7. Shock absorbers that allow excessive body sway 8. Tire condition, tread depth, and proper inflation pressure
WINDSHIELD WIPER AND WASHER FLUID SERVICE WINDSHIELD WIPERS Windshield wiper blades are constructed of rubber and tend to become brittle due to age. Wiper blades should be cleaned whenever the vehicle is cleaned using water and a soft cloth. Wiper blade or wiper blade insert replacement includes the following steps.
Turn the ignition switch to on (run).
Turn the wiper switch on and operate the wipers.
When the wipers are located in an easy-to-reach location, turn the ignition switch off. The wipers should stop.
Remove the insert or the entire blade as per service information and/or the instructions on the replacement windshield wiper blade package.
After double-checking that the wiper is securely attached, turn the ignition switch on (run).
Turn the wiper switch off and allow the wipers to reach the park position. Check for proper operation.
3. Windshield wiper operation 4. Mirrors 5. Defroster fan operation 6. Steering for excessive looseness or leaks
SEE FIGURE 17–3.
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UNDER HOOD
WIPER ARM
WIPER BLADE INSERT
FIGURE 17–3 Installing a wiper blade insert into a wiper arm.
GLOVE COMPARTMENT
FIGURE 17–5 A cabin filter can be accessed either through the glove compartment or under the hood on most vehicles.
Most windshield washer fluid looks like blue water. It is actually water with an alcohol (methanol) additive to prevent freezing and to help clean the windshield by dissolving bugs. Be careful not to spill any washer fluid when filling the reservoir because the corrosiveness can harm wiring and electronic components. CAUTION: Some mixed fluids are for summer use only and do not contain antifreeze protection. Read the label carefully!
WARNING Windshield washer fluid usually contains methanol, a poisonous chemical that can cause blindness if ingested.
CABIN FILTER REPLACEMENT
(a)
A cabin filter is used in the heating, ventilation, and air-conditioning (HVAC) system to filter the outside air drawn into the passenger compartment. Some filters contain activated charcoal to help eliminate odors. The cabin air filter should be replaced often—every year or every 12,000 miles (19,000 km). The cabin air filter can be accessed from:
Under the hood at the cowl (bulkhead) or
Under the dash, usually behind the glove (instrument panel) compartment (Check service information for the exact location and servicing procedures for the vehicle being serviced.)
SEE FIGURE 17–5.
(b)
FIGURE 17–4 (a) The windshield wiper fluid reservoir cap is usually labeled with a symbol showing a windshield washer. (b) Use only the recommended washer fluid. Never use antifreeze in the windshield washer reservoir.
WINDSHIELD WASHER FLUID Windshield washer fluid level should be checked regularly and refilled as necessary. Use only the fluid that is recommended for use in vehicle windshield washer systems. SEE FIGURE 17–4.
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AIR FILTER INSPECTION/ REPLACEMENT An air filter filters dirt from the air before it enters the intake system of the engine. The air filter should be replaced according to vehicle manufacturer’s recommendations. Over time, the filter will start to get clogged and decrease the engine’s efficiency. Many vehicle manufacturers recommend replacing the air filter every 30,000 miles (50,000 km), or more frequently under dusty conditions. Many service
(a)
FIGURE 17–7 A master cylinder with a transparent reservoir. The brake fluid level should be between the MAX and the MIN levels as marked on the reservoir.
Metal or nontransparent plastic reservoir. This type of reservoir used on older vehicles requires that the cover be removed to check the level of the brake fluid. The proper level of brake fluid should be 0.25 inch (6 mm) from the top.
CAUTION: Do not overfill a brake master cylinder. The brake fluid gets hotter as the brakes are used and there must be room in the master cylinder reservoir for the brake fluid to expand. (b)
FIGURE 17–6 (a) A typical dirty air filter. (b) Always check the inlet passage leading to the air filter for debris that can reduce airflow to the engine.
BRAKE FLUID TYPES Brake fluid is made from a combination of various types of glycol, a non-petroleum-based fluid. Brake fluid is a polyalkylene-glycol-ether mixture, called polyglycol for short. All polyglycol brake fluid is clear to amber in color.
technicians recommend replacing the air filter every year. SEE FIGURE 17–6.
CAUTION: DOT 3 brake fluid is a very strong solvent and can remove paint! Care is required when working with this type brake fluid to avoid contact with the vehicle’s painted surfaces. It also takes the color out of leather shoes.
BRAKE FLUID INSPECTION BRAKE FLUID LEVEL Brake fluid is used to transmit the force of the driver’s foot on the brake pedal, called the service brake, to each individual wheel brake. The brake fluid should be checked at the same time the engine oil is changed, or every six months, whichever occurs first. It is normal for the brake fluid level to drop as the disc brake pads wear. Therefore, when the fluid level is low, check for two possible causes.
All automotive brake fluid must meet Federal Motor Vehicle Safety Standard 116. The Society of Automotive Engineers (SAE) and the Department of Transportation (DOT) have established brake fluid specification standards.
DOT 3. The DOT 3 brake fluid is most often used. It absorbs moisture and, according to SAE, can absorb 2% of its volume in water per year. Moisture is absorbed by the brake fluid through microscopic seams in the brake system and around seals. Over time, the water will corrode the system and thicken the brake fluid. Moisture can cause a spongy brake pedal because the increased concentration of water within the fluid boils at lower temperatures and can result in vapor lock. DOT 3 must be used from a sealed (capped) container. If allowed to remain open for any length of time, DOT 3 will absorb moisture from the surrounding air. SEE FIGURE 17–8.
DOT 4. The DOT 4 brake fluid is formulated for use by all vehicles, imported or domestic. It is commonly called low moisture absorption (LMA) because it does not absorb water as fast as DOT 3. It is still affected by moisture, however, and should be used only from a sealed container. The cost of DOT 4 is approximately double the cost of DOT 3.
DOT 5. The DOT 5 type is commonly called silicone brake fluid. It is made from polydimethylsiloxanes. Because it does
CAUSE 1 Normal disc brake pad wear (Inspect the brakes if the fluid level is low.) CAUSE 2 A leak somewhere in the hydraulic brake system (Carefully inspect the entire brake system for leaks if the brakes are not worn and the brake fluid level is low.) There are two types of brake master cylinders.
Transparent reservoir. This type allows viewing of the brake fluid (and hydraulic clutch master cylinder if so equipped) without having to remove the cover of the reservoir. The proper level should be between the MIN (minimum) level indicated and the MAX (maximum) level indicated on the clear plastic reservoir. SEE FIGURE 17–7.
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FIGURE 17–9 Brake fluid test strips are a convenient and easyto-use method to determine if the brake fluid needs to be replaced.
? FIGURE 17–8 DOT 3 brake fluid. Always use fluid from a sealed container because brake fluid absorbs moisture from the air.
What Is Used in the Clutch Master Cylinder? Vehicles equipped with a manual transmission often use a hydraulically operated clutch. This type of clutch operation uses a master cylinder and a slave cylinder near the clutch assembly. When the driver depresses the clutch pedal, the hydraulic pressure created in the master cylinder is transferred to the slave cylinder which moves and actuates the clutch. Most hydraulic clutches use DOT 3 brake fluid. Check to see that the level is between the maximum and the minimum levels as shown by lines on the reservoir. If low, check for a leak in the system as it is not normal for brake fluid level to decrease over time.
not absorb water, it is called nonhygroscopic. DOT 5 brake fluid does not mix with and should not be used with DOT 3 or DOT 4 brake fluid. NOTE: Even though DOT 5 does not normally absorb water, it is still tested using standardized SAE procedures in a humidity chamber. After a fixed amount of time, the brake fluid is measured for boiling point. Because it has had a chance to absorb moisture, the boiling point after this sequence is called the minimum wet boiling point. DOT 5 brake fluid is purple (violet), to distinguish it from DOT 3 or DOT 4 brake fluid.
DOT 5.1. The DOT 5.1 brake fluid is a non-silicone-based polyglycol fluid that is clear to amber in color. This severeduty fluid has a boiling point of over 500°F,(260°C) equal to the boiling point of silicone-based DOT 5 fluid. Unlike DOT 5, the DOT 5.1 fluid can be mixed with either DOT 3 or DOT 4 according to the brake fluid manufacturer’s recommendations.
CAUTION: Some vehicle manufacturers, such as Chrysler, do not recommend the use of or the mixing of other types of polyglycol brake fluid and specify the use of DOT 3 brake fluid only. Always follow the vehicle manufacturer’s recommendation.
BRAKE FLUID TESTING
Visual inspection. Check the color of the brake fluid. It should be clear or almost clear. If it is dark brown or black, it should be replaced.
Test strips. A quick and easy way to check the condition of the brake fluid is to use test strips. Always follow the instructions that come with the test strips for accurate results. SEE FIGURE 17–9.
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FREQUENTLY ASKED QUESTION
Boiling point. The boiling point of brake fluid can be tested using a handheld tester. Follow the instructions that come with the tester.
CAUTION: If any mineral oil such as engine oil, automatic transmission fluid (ATF), or power steering fluid gets into the brake fluid, the rubber seals will swell and cause damage to the entire braking system. Every part that includes a rubber seal will require replacement.
ENGINE OIL INSPECTION OIL LEVEL
The oil level should be checked when the vehicle is parked on level ground and after the engine has been off for at least several minutes. The oil level indicator, commonly called a dipstick, is clearly marked and in a convenient location. SEE FIGURE 17–10. To check the oil, remove the dipstick, wipe off the oil, and reinsert it all the way down. Once again remove the dipstick and check where the oil level touches the indicator. The “add” mark is usually at the 1 quart low point. SEE FIGURE 17–11.
FIGURE 17–10 A typical oil level indicator (dipstick).
EN
G
IN
Normal Use
Severe Use
Most trips over 10 miles (16 km).
Most trips less than 4 to 10 miles (6 to 16 km).
Operating a vehicle when the outside temperature is above freezing (32°F/0°C).
Operating the vehicle when the outside temperature is below freezing (32°F/0°C).
Most trips do not include slow or stop-and-go driving.
Most trips include slow or stop-and-go driving.
Not towing a trailer or carrying a heavy load.
Towing a trailer or hauling a heavy load.
Driving without dusty conditions.
Driving in dusty conditions.
No police, taxi, or commercial use of the vehicle.
Use by police, taxi, or commercial operation.
The oil change interval recommended by most vehicle manufacturers under normal conditions is 7,500 miles (12,000 km) or six months, whichever occurs first.
The oil change interval recommended by most vehicle manufacturers operating under severe conditions is every 3,000 miles (4,800 km) or every three months, whichever occurs first.
E
O
IL
CHART 17–1 MIN
MAX
The difference been “normal” and “severe” use as specified by many vehicle manufacturers.
ADD 1 QT. AT MIN.
FIGURE 17–11 The oil level should be between the MAX and the MIN marks when the vehicle is on level ground and the oil has had time to drain into the oil pan.
?
FREQUENTLY ASKED QUESTION
?
FREQUENTLY ASKED QUESTION
How Does an Oil Life Monitor Work?
Can I Switch from Synthetic Oil to Regular Oil? Yes. All oil is miscible, meaning that it can be readily mixed. Therefore, synthetic oil can be used one time and then regular mineral oil used the next time. Most important, however, is that the oil be changed at intervals that are never longer than specified by the vehicle manufacturer.
If oil needs to be added, use the specified oil and add to the engine through the oil fill opening (not through the dipstick hole as is done with automatic transmission fluid).
ENGINE OIL CHANGE INTERVALS Most automotive experts recommend that the engine oil be replaced and a new oil filter installed every 5,000 to 7,500 miles (8,000 to 12,000 km) or every six months, whichever occurs first. Most vehicles since the early 2000s have used an oil life monitor system to notify the driver when the engine oil should be changed. The oil life monitor will light a dash lamp when the oil needs to be changed. Most vehicle manufacturers recommend that the oil be changed according to a “normal” or “severe use” schedule. SEE CHART 17–1. Most vehicles are driven under severe conditions if all of the factors above are considered. Always follow the vehicle manufacturer’s recommended oil change intervals. See Chapter 22 for details on oils and oil change procedure.
While some vehicle manufacturers, such as Mercedes, use a sensor to measure oil temperature and acidity, most vehicle oil change monitors function three ways: 1. Vehicle mileage. This is the most commonly used vehicle service monitoring system. When a certain number of miles has occurred since it was reset, the control (usually the powertrain control module (PCM)) will turn on a dash light that states maintenance is required. 2. Oil life computer program. A computer program called an algorithm, or a series of mathematical calculations, is used to determine the life of the engine oil. For example, when the oil change warning light is reset, the oil life is reset to 100%. Then the PCM tracks the number of engine starts, the outside temperature, when the engine was started (based on intake air temperature [IAT] sensor input), and the number of miles traveled. Because long drives are easier on engine oil than short stop-and-go driving, the PCM deducts numbers faster during this condition. 3. Oil condition sensor. This sensor measures the dielectric properties of the oil, which changes when exposed to water, soot, ash, and glycol in the oil. A computer program takes the information from the sensor about the changes of the dielectric property of the oil to determine when to light the “change oil” lamp.
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WARNING Remove the pressure cap only on a cold engine as the coolant will boil when pressure is released. This occurs because the coolant temperature is above the boiling point but it does not boil due to the pressure. When the pressure is released, all of the hot coolant immediately boils and expands outward from the opening where the cap was installed. The resulting geyser of boiling hot coolant can cause serve burns or even death.
FIGURE 17–12 Visually check the level and color of coolant in the coolant recovery or surge tank.
3. Maintenance should also include a visual inspection for signs of coolant system leaks and for the condition of the coolant hoses and accessory drive belts.
COOLANT TESTING
?
FREQUENTLY ASKED QUESTION
Visual inspection. Coolant should be clean and close to the color when it was new. If dark or muddy, it should be replaced. Milky colored coolant is an indication of oil in the system that might be caused by a defective engine gasket. If the coolant is dark or muddy looking, it should be replaced.
Test strips. Coolant test strips are available to test the condition of the coolant. Check to see that the test strips are being used on the specified type of coolant as some will work only on the old green inorganic additive technology (IAT) coolant.
Boiling/freezing points (refractometer and hydrometer). A hydrometer can be used to check the freezing and boiling temperatures of the coolant. A refractometer can be used to check the freezing temperature of the coolant.
Proper reading. A proper 50-50 mix of antifreeze and water should result in a freezing temperature of ⫺34°F (⫺37°C).
What Is the Magnuson-Moss Act? The Magnuson-Moss Act, passed into law in 1975, allows the use of non–original equipment replacement parts during the service or repair of a vehicle without losing the factory warranty. This means that any oil or air filter, spark plug, or other service part can be used unless the vehicle manufacturer furnishes these parts for free during the warranty period. The vehicle manufacturer cannot deny paying a warranty claim for a fault unless the replacement part is proved to be the cause of the condition needed to be covered by the warranty. Therefore, it is up to the business owner, service manager, or technician to determine if the replacement part is of good quality. While this is very difficult or impossible, unless defects are obviously visible, the best solution is to use the original equipment manufacturer (OEM) parts or service parts from a well-known company.
COOLING SYSTEM INSPECTION
If the freezing temperature is higher than ⫺34°F (such as ⫺20°F), there is too much water in the coolant. If the freezing temperature is lower than ⫺34°F (such as ⫺46°F), there is too much antifreeze in the coolant. SEE FIGURE 17–13.
NOTE: Many hybrid electric vehicles use two separate cooling systems—one for the internal combustion engine (ICE) and the other to cool the electronics. Check service information for the exact procedures to follow. See Chapter 20 for more details on coolant and coolant testing.
STEPS INVOLVED
Normal maintenance involves an occasional check of the following items. 1. Coolant level in the coolant recovery tank or in the surge tank SEE FIGURE 17–12. 2. The front of the radiator should be carefully inspected and cleaned of bugs, dirt, or mud that can often restrict airflow.
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ANTIFREEZE/COOLANT DISPOSAL
Used coolant drained from vehicles can usually be disposed of according to federal, state, and local laws. Check with recycling companies authorized by local or state government for the exact method recommended for disposal in your area. SEE FIGURE 17–14.
(a)
FIGURE 17–15 Using a hand-operated pressure tester. Do not exceed the pressure rating of the radiator cap when pressurizing the system. This vehicle had a leaking upper radiator that only leaked when the system was pressurized.
sucked closed, since the lower hose is attached to the suction side of the water pump. The bypass hose (if equipped) and heater hoses come in the following inside diameter sizes.
(b)
FIGURE 17–13 (a) A refractometer is used to measure the freezing point of coolant. A drop of coolant is added to a viewing screen, the lid is closed, and then held up to the light to view the display on the tool. (b) The use of tests strips is a convenient and cost-effective method to check coolant condition and freezing temperature.
1/2 inch
5/8 inch
3/4 inch
The heater hoses connect the engine cooling system to the heater core. A heater core looks like a small radiator and is located inside the vehicle. All automotive hose is constructed of rubber with reinforcing fabric weaving for strength. Sections of the coolant lines can be made from nylon-reinforced plastic or metal. All hoses should be inspected for leaks (especially near hose clamps), cracks, swollen areas indicating possible broken reinforcing material, and excessively brittle, soft, and swollen sections. Using a hand-operated pressure pump attached to the radiator opening is an excellent way to check for leaks. SEE FIGURE 17–15.
EMISSION-RELATED HOSES
Rubber hoses are also used in the following locations and for the following purposes.
FIGURE 17–14 Used coolant should be stored in a leak-proof container until it can be recycled or disposed of according to local, state, or federal laws. Note that the storage barrel is placed inside another container to catch any coolant that may spill out of the inside container.
RADIATOR AND HEATER HOSES
Upper and lower radiator hoses must be pliable, yet not soft. The lower radiator hose will be reinforced or contain an inner spring to prevent the hose from being
Positive crankcase ventilation (PCV) system hose. This type of hose has engine vacuum and requires specially designed hose if replacing the hose used for the PCV system.
Exhaust gas recirculation (EGR) system hose. This type of hose has engine vacuum and requires specially designed hose if replacing the hose used for the EGR system.
Secondary air injection (SAI) system hoses. This type of hose has engine vacuum or low pressure air and requires specially designed hose if replacing the hose used for the SAI system.
HOSE CLAMPS
There are several types of hose clamps used depending on the make, model, and year of vehicle. The three basic types are as follows: 1. Worm drive (also called a screw band type) 2. Banded-type clamp 3. Wire clamp (spring type) SEE FIGURE 17–16.
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WORM-TYPE CLAMP
BANDED-TYPE CLAMP
WIRE-TYPE CLAMP
TR
A
N
S
FL
UI
D
Add 1 pt. or .5 L
Full hot
FIGURE 17–17 A typical automatic transmission dipstick. SCREWDRIVER
To check the automatic transmission fluid, perform the following steps.
HOSE CLAMP PLIERS
FIGURE 17–16 Hose clamps come in a variety of shapes and designs.
TECH TIP The Cut-and-Peel Trick It is often difficult to remove a radiator or heater hose from the fittings on the radiator or heater core. To avoid possible damage to expensive radiator or heater cores, do not pull or twist the hose to remove it. Simply use a utility knife and slit the hose lengthwise and then use your finger to peel the hose off of the radiator or heater core. Although this procedure will not work if the hose is to be reused, it is a real time saver when it comes to replacing old hoses. Sometimes using an angled pick that is dulled at the end will do a good job breaking the hose free.
STEP 1
Start the engine and move the gear selector to all gear positions and return to park or neutral as specified by the vehicle manufacturer.
STEP 2
Remove the transmission/transaxle dipstick (fluid level indicator) and wipe it off using a clean cloth.
STEP 3
Reinsert the dipstick until fully seated. Remove the dipstick again and note the level. SEE FIGURE 17–17.
NOTE: Some transmissions or transaxles do not use a dipstick. Check service information for the exact procedure to follow to check the fluid level. Some vehicles require the use of a scan tool to check the level of the fluid.
NOTE: The “add” mark on most automatic transmission/ transaxle dipsticks means that 1/2 quart (1/2 liter) of automatic transmission fluid needs to be added.
AUTOMATIC TRANSMISSION FLUID CHECK STEPS INVOLVED
The automatic transmission fluid (ATF) is another important fluid that should be checked regularly. Most automatic transmission fluid levels should be checked under the following conditions.
The vehicle should be parked on a level surface.
The transmission fluid should be at normal operating temperature. This may require the vehicle to be driven several miles before the level is checked.
The engine should be running with the transmission in neutral or park as specified by the vehicle manufacturer.
NOTE: Honda and Acura manufacturers usually specify that the transmission fluid be checked with the engine off. The recommended procedure is usually stamped on the transmission dipstick or written in the owner’s manual and/or service manual.
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Do not overfill any automatic transmission/transaxle. Even if just 1/2 quart too much were added by mistake (for example, adding 1 quart when the fluid was at the “add” line instead of the correct amount of 1/2 quart) could cause the fluid to foam. Foaming of the ATF is caused by the moving parts inside the transmission/transaxle, which stir up the fluid and introduce air into it. This foamy fluid cannot adequately lubricate or operate the hydraulic clutches that make the unit function correctly.
Smell the ATF on the dipstick. If it seems burned or rancid, further service of the automatic transmission/transaxle will be necessary. Look at the color of the fluid. It should be red or light brown. A dark brown or black color indicates severe oxidation usually caused by too high an operating temperature. Further service and diagnosis of the automatic transmission/ transaxle will be required.
NOTE: Chrysler warns that color and smell should not be used to determine the condition of ATF⫹4 used in most Chrysler-built vehicles since the 2000 model year. The dyes and additives can change during normal use and it is not an indication of fluid contamination. This is true for most highly friction-modified ATF. Always follow the vehicle manufacturer’s recommendation.
TYPES OF AUTOMATIC TRANSMISSION FLUID
Automatic transmission fluid is high-quality oil that has additives that resist oxidation, inhibit rust formation, and allow the fluid to flow easily at all temperatures. The automatic transmission fluid is dyed red for identification. Various vehicle manufacturers recommend a particular type of ATF based mainly on its friction characteristics. Friction is needed between the bands, plates, and clutches of an automatic transmission/transaxle.
FIGURE 17–18 Most vehicles use a combination filler cap and level indicator (dipstick) that shows the level of power steering fluid in the reservoir.
TECH TIP
FIGURE 17–19 A special tool is useful when installing a new accessory drive belt. The long-handled wrench fits in a hole of the belt tensioner.
The Paper Towel Test New ATF will penetrate a paper towel better than used oxidized ATF. To compare old fluid with new, place three drops of new fluid on a paper towel and three drops of used ATF on the paper towel about 3 inches from the first sample. Wait for 30 minutes. The new ATF will have expanded (penetrated through the paper towel) much farther than the old, oxidized fluid. This test can be used to convince a customer that the ATF should be changed according to the vehicle manufacturer’s recommended interval even though, to the naked eye, the fluid looks okay.
The types of power steering fluid can include:
Automatic transmission fluid (check for the exact type)
Power steering fluid
Unique fluid that is specially designed for the vehicle
CAUTION: Do not use fluid that is labeled for all vehicles as this type may not be compatible with the seals used in the power steering system or provide the specified friction additives needed to provide the proper steering feel to the driver.
See Chapter 128 for additional information about automatic transmission fluid and service procedures. Always use the exact ATF recommended by the vehicle manufacturer.
ACCESSORY DRIVE BELT INSPECTION
POWER STEERING FLUID CHECKING POWER STEERING FLUID Check power steering fluid level with the engine off. The cap for the power steering reservoir is marked with an icon of a steering wheel or the words “power steering.” Remove the cap by twisting it counterclockwise and use the level indicator as part of the cap to determine the level. Often the level marks are for cold and hot fluid.
If too low, check for leaks especially at the high-pressure lines and fittings. Add the specified fluid to the correct level. If too high, use a fluid siphon pump or a “turkey baster” and remove the excess fluid until the level is correct.
TYPES OF POWER STEERING FLUID
The correct power steering fluid is critical to the operation and service life of the power steering system! The exact power steering fluid to use varies by vehicle manufacturer and sometimes between models made by the same vehicle manufacturer because of differences among various steering component manufacturers. Always check service information for the specified fluid to use. SEE FIGURE 17–18.
TYPES OF BELTS
Older V-belts (so-named because of their shape) are 34 degrees at the V. The pulley they ride through is generally 36 degrees. This 2-degree difference results in a wedging action and makes power transmission possible, but it is also the reason why V-belts must be closely inspected. It is generally recommended that all belts, including the serpentine (or Poly V) belts be replaced every four to seven years. When a belt that turns the water pump breaks, the engine could rapidly overheat causing serious engine damage, and if one belt breaks, it often causes the other belts to become tangled, causing them to break. SEE FIGURES 17–19 AND 17–20.
BELT TENSION MEASUREMENT There are four ways that vehicle manufacturers specify that the belt tension is within factory specifications. 1. Belt tension gauge. A belt tension gauge is needed to achieve the specified belt tension. Install the belt and operate the engine with all of the accessories turned on to “run-in” the belt
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FIGURE 17–20 A typical worn serpentine accessory drive belt. Newer belts made from ethylene propylene diene monomer (EPDM) do not crack like older belts that were made from neoprene rubber. FIGURE 17–22 A spring-loaded accessory drive belt tensioner.
TECH TIP The Water Spray Trick
FIGURE 17–21 A belt tension gauge displays the belt tension in pounds of force.
for at least five minutes. Adjust the tension of the accessory drive belt to factory specifications or use the table below for an example of the proper tension based on the size of the belt. SEE FIGURE 17–21. Serpentine Belts Number of Ribs Used
Tension Range (lb)
3
45–60
4
60–80
5
75–100
6
90–125
7
105–145
V-Belts V-Belt Top Width (in.)
Tension Range (lb)
1/4
45–65
5/16
60–85
25/64
85–115
31/64
105–145
Lower-than-normal alternator output could be the result of a loose or slipping drive belt. All belts (V and serpentine multigroove) use an interference angle between the angle of the Vs of the belt and the angle of the Vs on the pulley. Over time this interference angle is worn off the edges of the V of the belt. As a result, the belt may start to slip and make a squealing sound even if tensioned properly. A fast method to determine if the noise is from the belt is to spray water from a squirt bottle at the belt with the engine running. If the noise stops, the belt is the cause of the noise. The water quickly evaporates; therefore, water simply finds the problem, it does not provide a short-term fix.
2. Marks on a tensioner. Many tensioners have marks that indicate the normal operating tension range for the accessory drive belt. Check service information for the preferred location of the tensioner mark. SEE FIGURE 17–22. 3. Torque wrench reading. Some vehicle manufacturers specify that a beam-type torque wrench be used to determine the torque needed to rotate the tensioner. If the torque reading is below specifications, the tensioner must be replaced. 4. Deflection. Depress the belt between the two pulleys that are the farthest apart and the flex or deflection should be 0.5 inch.
BELT ROUTING GUIDE
Always check the belt routing diagram located on the underhood sticker or in service information for the proper routing when replacing an accessory drive belt. The belt routing can vary depending on engine size and accessories.
TIRE AND WHEEL SERVICE INFLATION PRESSURE
Replace any serpentine belt that has more than three cracks in any one rib that appears in a 3 inch span.
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Tire pressure should be checked when the tires are cold. As a vehicle is driven, the flexing of the tire and friction between the tire and the road causes an increase in temperature.
FIGURE 17–23 The specified tire inflation pressure is printed on a placard on the driver’s door or doorpost. This information may also be located in the glove compartment, the owner’s manual, and in service information.
As the tire heats up, the air inside the tire also increases in temperature.
The increased temperature of the air increases the air pressure inside the tire.
The air pressure typically increases in pressure 4 to 6 psi after the vehicle has been driven several miles.
If air is then removed from the hot tire, the tire would be underinflated. The tire pressure specified is for a tire that has not been driven and is therefore cold, so the air pressure should be checked before the vehicle has been driven more than 2 miles (3 km).
FIGURE 17–24 An electronic tire pressure gauge is usually more accurate than a mechanical “pencil type” gauge and more likely to provide consistent pressure readings. Do not allow air to escape when testing or the reading will not be accurate. TECH TIP
NOTE: Tire pressure changes according to air temperature about 1 psi per 10°F; therefore, during a change of season the tire pressure has to be adjusted. For example, when the summer temperature of 80°F changes to 40°F in the fall, the tire pressure will drop about 4 psi (80 ⴚ 40 ⴝ 40).
Two Quick Checks If the vehicle is hoisted on a frame-contact lift, perform two quick checks: 1. Spin each tire to check that the brakes are not dragging. You should be able to turn all four wheels by hand if the parking brake is off and the transmission is in neutral. 2. When spinning the tire, look over the top of the tire to check if it is round. An improperly mounted tire or a tire that is out-of-round due to a fault in the tire can be detected by watching for the outside of the tire to move up and down as it is being rotated.
HOW TO CHECK TIRE PRESSURE Use a good-quality tire pressure gauge and push it against the tire valve stem after removing the cap. Be sure no air escapes when the pressure gauge is used as this will cause an inaccurate reading. Compare the pressure reading with the specified tire pressure. The specified pressure is located on a placard attached to the driver’s door or doorpost or in the glove compartment. SEE FIGURE 17–23. CAUTION: Do not inflate tires to the maximum rating on the tire sidewall. Even though this pressure represents the maximum tire pressure, inflating the tires to this pressure usually results in a very harsh ride and often unacceptable handling.
SPECIFIED TIRE PRESSURE
The specified tire inflation pressure should always be used when checking or adjusting tire pressure. Tire pressure should be checked and adjusted if necessary after a tire rotation has been completed because some vehicles require different inflation pressure for front and rear tires. Therefore, when the tires are rotated, the front and rear tire inflation pressure may need to be adjusted. The spare tire should also be checked at each oil change interval. Check service information for the exact inflation pressure. The recommendation sometimes includes a statement about tire pressures to use if operating under all highway-driving conditions or operating the vehicle in a fully loaded condition. Specifications for these conditions commonly include increasing the pressure, usually about 4 to 6 psi (27 to 41 kPa). SEE FIGURE 17–24.
TIRE INSPECTION
All tires should be carefully inspected for faults in the tire itself or for signs that something may be wrong with
the steering or suspension systems of the vehicle. The tires should be checked for the following conditions.
Thread depth (2/32 of an inch is the standard minimum allowable tread depth in most states)
Unequal wear
Cuts in the tread or sidewall
Bulges or uneven sidewalls
Check the spare tire for proper inflation pressure as well as condition of the tire and wheel. See Chapter 114 for additional information on tire service procedure.
TIRE ROTATION To assure long life and even tire wear, it is important to rotate each tire to another location. Some rear-wheeldrive vehicles, for example, may show premature tire wear on the front tires. The wear usually starts on the outer tread row and usually appears as a front-to-back (high and low) wear pattern on individual tread blocks. These blocks of tread rubber are deformed during cornering, stopping, and turning, which can cause tire noise and/or tire roughness. While some shoulder wear on front tires is normal, it can be reduced by proper inflation, alignment, and tire rotation. SEE FIGURE 17–25 for suggested methods of rotation.
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FRONT-WHEEL DRIVE
REAR-WHEEL DRIVE
FRONT
FRONT
(a) MODIFIED "X"
(PREFERRED METHOD) FRONT OR REAR WHEEL DRIVE
FRONT OR REAR WHEEL DRIVE
FRONT
FRONT
(b)
FIGURE 17–26 (a) A torque absorbing adaptor commonly called a “torque stick” is being used to tighten lug nuts. The adapter should not be held during the tightening process because this can affect the torque applied and could cause personal injury if the torque stick broke. (b) A color-coded assortment of torque sticks. FULL "X"
FRONT/REAR
(ACCEPTABLE)
(ACCEPTABLE)
FIGURE 17–25 The method most often recommended is the modified X method. Using this method, each tire eventually is used at each of the four wheel locations. An easy way to remember the sequence, whether front-wheel drive or rear-wheel drive, is “Drive wheels straight, cross the nondrive wheels.” NOTE: Radial tires can cause a radial pull due to their construction. If the wheel alignment is correct, attempt to correct a pull by rotating the tires front to rear or, if necessary, side to side. HINT: To help remember when to rotate the tires, just remember that it should be done at every other oil change. Most manufacturers recommend changing the engine oil every 5,000 miles (8,000 km) or every six months and recommend tire rotation every 10,000 (16,000 km) miles or every year.
WHEEL MOUNTING TORQUE There are two commonly used methods to ensure proper tire lug nut torque.
Torque wrench. Using a torque wrench is the preferred method to tighten the wheel lug nuts.
Torque sticks. These long sticks are calibrated to transmit a limited amount of torque to the lug nut when used according to factory instructions. Make certain that the wheel studs are
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TECH TIP Check for Wheel Lock Key Many vehicles have wheel locks that require a special key to remove. The wise technician should always ask the customer or service writer about wheel locks before pulling the vehicle into the shop or before the vehicle is hoisted.
clean and dry and torqued to manufacturer’s specifications. Most vehicles specify a tightening torque of between 80 and 100 lb-ft (108 and 136 N-m). CAUTION: Most manufacturers warn that the wheel studs should not be oiled or lubricated with grease because this can cause the wheel lug nuts to loosen while driving. Always tighten lug nuts gradually, in the proper sequence (tighten one nut, skip one, and tighten the next nut), to prevent warping the brake drums or rotors, or bending a wheel. SEE FIGURE 17–26. NOTE: Anytime you install a brand-new set of aluminum wheels, retorque the wheels after the first 25 miles. The soft aluminum often compresses slightly, loosening the torque on the wheels.
FIGURE 17–27 A hand-operated grease gun is being used to lubricate the steering component through a grease fitting.
FIGURE 17–28 Most vehicle manufacturers recommend the use of grease meeting the NLGI #2 and “GC” for wheel bearings and “LB” for chassis lubrication. Many greases have both designations and therefore can be used for wheel bearings or chassis lubrication.
REAL WORLD FIX
TECH TIP
Waiting for the Second Click Story A student service technician was observed applying a lot of force to a clicker-type torque wrench attached to a wheel lug nut. When the instructor asked what he was doing, the student replied that he was turning the lug nut tighter until he heard a second click from the torque wrench. This was confusing to the instructor until the student explained that he had heard a second click of the torque wrench during the demonstration. The instructor at once realized that the student had heard a click when the proper torque was achieved, plus another click when the force on the torque wrench was released. No harm occurred to the vehicle because all of the lug nuts were reinstalled and properly torqued. The instructor learned that a more complete explanation for the use of click-type torque wrenches was needed.
Watch Out for Vents that Look Like Grease Fittings Watch for what looks like a grease (Zerk) fitting but is somewhat smaller, as this may be a vent such as found on a late-model Dodge Caravan on the ball joints. If the grease gun does not fit on it, do not be tempted to remove and replace with a grease fitting. STEP 4
If the fitting will not accept grease, replace it with a new one and retry.
STEP 5
Remove the grease gun and wipe any spilled grease from the fitting.
CAUTION: If too much grease is forced into a sealed grease boot, the boot itself may rupture, requiring the entire joint to be replaced.
TYPES OF GREASE Vehicle manufacturers specify the type and consistency of grease for each application. The technician should know what these specifications mean. Grease is oil with a thickening agent added to allow it to be installed in places where a liquid lubricant would not stay. Greases are named for their thickening agent, such as aluminum, barium, calcium, lithium, or sodium.
CHASSIS LUBRICATION GREASE FITTINGS
Chassis lubrication refers to the greasing of parts that rub against each other or installing grease into a pivot (or ball joints) through a grease fitting. Grease fittings are also called Zerk fittings (named for Oscar U. Zerk) or Alemite fittings (named for the manufacturer of early grease fittings). These fittings contain a one-way check valve that prevents the grease from escaping. Grease fittings are used on steering components, such as tie-rod ends, and in the suspension ball joints, which require lubrication to prevent wear and noise caused by the action of a ball rotating within a joint during vehicle operation. SEE FIGURE 17–27. The procedure for greasing a grease fitting includes the following steps. STEP 1
Wipe off the fitting with a shop cloth.
STEP 2
Make sure the grease gun coupler is fully seated on the fitting.
STEP 3
Apply grease only until the dust boot swells.
CAUTION: Grease types are often not compatible with each other. The American Society for Testing Materials (ASTM) specifies the consistency of grease using a penetration test. The National Lubricating Grease Institute (NLGI) uses the penetration test as a guide to assign the grease a number. Low numbers are very fluid and higher numbers are more firm or hard. Most vehicle manufacturers specify NLGI #2 for wheel bearing and chassis lubrication. SEE FIGURE 17–28. NLGI also specifies grease by its use, as follows:
The “GC” designation is acceptable for wheel bearings.
The “LB” designation is acceptable for chassis lubrication.
Many greases are labeled with both GC and LB and are therefore acceptable for both wheel bearings and chassis use, such as in lubricating ball joints and tie-rod ends.
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FILL PLUG (INSPECTION HOLE)
DRAIN PLUG
FIGURE 17–29 This differential assembly has been leaking fluid. The root cause should be determined and the unit filled to the proper level using the specified lubricant, to help prevent early failure and an expensive repair later.
FIGURE 17–30 Always ensure that the fill plug can be accessed and removed before draining the fluid from a manual transmission.
TECH TIP Check the Fill Plug Before Draining a Transmission Experienced technicians have learned that it is wise to check that the fill plug can be removed before draining the manual transmission or transfer case through the drain plug. If the fill plug cannot be removed, then the fluid should not be drained until the problem is resolved. Once the fluid has been drained, there is no option but to do whatever it takes to get the fill plug open. This process is often difficult and may result in having to replace the entire assembly. SEE FIGURE 17–30.
DIFFERENTIAL FLUID CHECK PROCEDURE FOR CHECKING
Rear-wheel-drive vehicles use a differential in the rear of the vehicle to change the direction of power flow from the engine to the rear wheels. The differential also provides a gear reduction to increase engine torque applied to the drive wheels. Four-wheel-drive vehicles also use a differential at the front of the vehicle in addition to the differential in the rear. To check the differential fluid level and condition, perform the following steps.
STEP 1
Hoist the vehicle safely.
STEP 2
Visually check for any signs of leakage. SEE FIGURE 17–29.
STEP 3
Remove the inspection plug from the side or rear cover of the differential assembly.
STEP 4
Insert your small finger into the hole in the housing and then remove your finger. If the differential fluid is on your finger, then the fluid level is okay. Rub the fluid between your fingers. If the fluid is not gritty feeling, reinstall the inspection plug. If the fluid is gritty feeling, further service will be necessary to determine the cause and correct it. If the differential fluid is not on your finger, then the fluid level is too low.
NOTE: The reason for the low fluid level should be determined. If repairs are not completed immediately, additional differential fluid should be added by pumping it into the differential through the inspection hole.
DIFFERENTIAL LUBRICANTS
All differentials use hypoid gear sets; and a special lubricant is necessary because the gears both roll and slide between their meshed teeth. Gear lubes are specified by the American Petroleum Institute (API). Most differentials require: 1. SAE 80W-90 GL-5 or
MANUAL TRANSMISSION/ TRANSAXLE LUBRICANT CHECK TYPES OF MANUAL TRANSMISSION FLUID Manual transmissions/transaxles may use any one of the following lubricants.
Gear lube (usually SAE 80W-90)
Automatic transmission fluid (ATF)
Engine oil (usually SAE 5W-30)
Manual transmission fluid (sometimes called synchromesh transmission fluid, or STF). This type of lubricant is similar to ATF, with special additives to ease shifting especially when cold.
PROCEDURE FOR CHECKING
To check manual transmissions/ transaxles lubricant, perform the following:
Hoist the vehicle safely.
Locate the transmission/transaxle inspection (fill) plug. Consult the factory service manual for the proper plug to remove, to check the fluid level.
If the fluid drips out of the hole, then the level is correct. If the fluid runs out of the hole, the level is too full. Allow it to flow out until it stops. The correct level of fluid is at the bottom of the inspection hole.
If low, first determine the correct fluid to use and then fill until the fluid level is at the bottom of the inspection hole or until the fluid runs out of the inspection hole.
2. SAE 75W-90 GL-5 or 3. SAE 80W GL-5 Limited slip differentials (often abbreviated LSD) often use an additive that modifies the friction characteristics of the rear axle lubricant to prevent chattering while cornering.
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"WITNESS MARK"
BROKEN END OF COIL SPRING
FIGURE 17–31 A broken coil spring was found during an undervehicle inspection. The owner was not aware of a problem and it did not make any noise, but the vehicle stability was affected.
UNDER-VEHICLE INSPECTION
FIGURE 17–32 This corroded muffler was found during a visual inspection, but was not detected by the driver because it was relatively quiet.
Brake lines for evidence of damage or leakage
Shock absorbers for leakage or damaged mounts
Steering linkage for obvious looseness or damaged or missing parts
Parking brake cable guides
VISUAL CHECKS
Other items underneath the vehicle that may need checking or lubricating include:
Shock absorbers and springs. SEE FIGURE 17–31.
Transmission/transaxle shift linkage (check the service manual for the correct lubricant to use)
Exhaust system including all pipes and hangers. SEE FIGURE 17–32.
CAUTION: Do not lubricate plastic-coated parking brake cables. The lubricant can destroy the plastic coating.
REVIEW QUESTIONS 1. Why should brake fluid not be filled above the full or MAX level as indicated on the master cylinder reservoir? 2. Why should brake fluid be kept in an airtight container?
3. How do you check differential fluid? 4. What are four lubricants that a manual transmission/transaxle may require depending on exact year, make, and model of the vehicle.
CHAPTER QUIZ 1. When should the engine oil be replaced? a. According to the vehicle manufacturer’s recommended interval based on time and mileage, whichever occurs first b. Every three months regardless of miles c. Every 3,000 miles regardless of time d. All of the above
5. Coolant can be checked using ______________. a. Boiling/freezing points using a refractometer and hydrometer b. Visual inspection c. Test strips d. All of the above
2. Most vehicle manufacturers specify brake fluid that meets what specification? a. DOT 2 c. DOT 4 b. DOT 3 d. DOT 5
6. Accessory drive belt tension is determined by ______________. a. Marks on the tensioner b. Torque required to rotate the tensioner using a beam-type torque wrench c. Belt tension using a belt tension gauge d. Any of the above depending on the specified procedure as found in service information.
3. The cabin filter can be accessed from ______________. a. Under the hood on some vehicles b. Under the dash on some vehicles c. From under the vehicle on some vehicles d. Either a or b 4. Before draining a manual transmission to replace the fluid, what should the technician do first? a. Check service information for the specified fluid b. Check to see if the fill plug can be removed c. Purchase SAE 80W-90 gear lube d. Both a and b
7. Using the modified X tire rotation method on a front-wheel-drive vehicle would place the right front tire on the ______________. a. Left front c. Right rear b. Left rear d. Right front 8. Most vehicle manufacturers specify a lug nut (wheel nut) tightening torque specification of about ______________. a. 80 to 100 lb-ft c. 125 to 150 lb-ft b. 100 to 125 lb-ft d. 150 to 175 lb-ft
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9. A grease labeled NLGI #2 GC is suitable for use on what vehicle components? a. Wheel bearings b. Chassis parts c. Both wheel bearings and chassis parts d. Door hinges only
S E C T I O N
VI
10. A service technician removed the inspection/fill plug from the differential of a rear-wheel- drive vehicle and gear lube started to flow out. Technician A says to quickly replace the plug to prevent any more loss of gear lube. Technician B says to catch the fluid and allow the fluid to continue to drain. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
Engine Repair
18 Gasoline Engine Operation, Parts, and Specifications
29 Engine Cleaning and Crack Detection
19 Diesel Engine Operation and Diagnosis
30 Cylinder Head and Valve Guide Service
20 Coolant
31 Valve and Seat Service
21 Cooling System Operation and Diagnosis
32 Camshafts and Valve Trains
22 Engine Oil
33 Pistons, Rings, and Connecting Rods
23 Lubrication System Operation and Diagnosis
34 Engine Blocks
24 Intake and Exhaust Systems
35 Crankshafts, Balance Shafts, and Bearings
25 Turbocharging and Supercharging
36 Gaskets and Sealants
26 Engine Condition Diagnosis
37 Engine Assembly and Dynamometer Testing
27 In-Vehicle Engine Service
38 Engine Installation and Break-in
28 Engine Removal and Disassembly
chapter
18
GASOLINE ENGINE OPERATION, PARTS, AND SPECIFICATIONS
OBJECTIVES: After studying Chapter 18, the reader should be able to: • Prepare for Engine Repair (A1) ASE certification test content area “A” (General Engine Diagnosis). • Explain how a four-stroke cycle gasoline engine operates. • List the various characteristics by which vehicle engines are classified. • Discuss how a compression ratio is calculated. • Explain how engine size is determined. • Describe how displacement is affected by the bore and stroke of the engine. KEY TERMS: Block 147 • Bore 152 • Bottom dead center (BDC) 149 • Boxer 149 • Cam-in-block design 150 • Camshaft 150 • Combustion 147 • Combustion chamber 147 • Compression ratio (CR) 155 • Connecting rod 149 • Crankshaft 149 • Cycle 149 • Cylinder 149 • Displacement 154 • Double overhead camshaft (DOHC) 151 • Exhaust valve 149 • External combustion engine 147 • Four-stroke cycle 149 • Intake valve 149 • Internal combustion engine 147 • Mechanical force 147 • Mechanical power 147 • Naturally aspirated 151 • Nonprincipal end 152 • Oil galleries 148 • Overhead valve (OHV) 150 • Pancake 149 • Piston stroke 149 • Principal end 152 • Pushrod engine 150 • Rotary engine 152 • Single overhead camshaft (SOHC) 150 • Stroke 154 • Supercharger 151 • Top dead center (TDC) 149 • Turbocharger 151 • Wankel engine 152
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PURPOSE AND FUNCTION The purpose and function of an engine is to convert the heat energy of burning fuel into mechanical energy. In a typical vehicle, mechanical energy is then used to perform the following:
Propel the vehicle
Power the air-conditioning system and power steering
Produce electrical power for use throughout the vehicle
ENERGY AND POWER Engines use energy to produce power. The chemical energy in fuel is converted to heat energy by the burning of the fuel at a controlled rate. This process is called combustion. If engine combustion occurs within the power chamber, the engine is called an internal combustion engine.
FIGURE 18–1 The rotating assembly for a V-8 engine that has eight pistons and connecting rods and one crankshaft.
NOTE: An external combustion engine burns fuel outside of the engine itself, such as a steam engine. Engines used in automobiles are internal combustion heat engines. They convert the chemical energy of the gasoline into heat within a power chamber that is called a combustion chamber. Heat energy released in the combustion chamber raises the temperature of the combustion gases within the chamber. The increase in gas temperature causes the pressure of the gases to increase. The pressure developed within the combustion chamber is applied to the head of a piston to produce a usable mechanical force, which is then converted into useful mechanical power.
FIGURE 18–2 A cylinder head with four valves per cylinder, two intake valves (larger) and two exhaust valves (smaller).
?
ENGINE CONSTRUCTION OVERVIEW
FREQUENTLY ASKED QUESTION
What Is a Flat-Head Engine?
BLOCK All automotive and truck engines are constructed using a solid frame, called a block. A block is constructed of cast iron or aluminum and provides the foundation for most of the engine components and systems. The block is cast and then machined to very close tolerances to allow other parts to be installed. ROTATING ASSEMBLY Pistons are installed in the block and move up and down during engine operation. Pistons are connected to connecting rods, which connect the pistons to the crankshaft. The crankshaft converts the up-and-down motion of the piston to rotary motion, which is then transmitted to the drive wheels and propels the vehicle. SEE FIGURE 18–1.
A flat-head engine is an older type engine design that has the valves in the block. The valves are located next to the cylinders and the air-fuel mixture, and exhaust flows through the block to the intake and exhaust manifolds. Because the valves are in the block, the heads are flat and, therefore, are called flat-head engines. The most commonly known was the Ford flat-head V-8 produced from 1932 until 1953. Typical flat-head engines included: • • • • •
Inline 4-cylinder engines (many manufacturers) Inline 6-cylinder engines (many manufacturers) Inline 8-cylinder engines (many manufacturers) V-8s (Cadillac and Ford) V-12s (Cadillac and Lincoln)
ENGINE PARTS AND SYSTEMS
CYLINDER HEADS
All engines use a cylinder head to seal the top of the cylinders, which are in the engine block. The cylinder head also contains both intake valves that allow air and fuel into the cylinder and exhaust valves, which allow the hot gases left over to escape from the engine. Cylinder heads are constructed of cast iron or aluminum and are then machined for the valves and other valverelated components. SEE FIGURE 18–2.
INTAKE AND EXHAUST MANIFOLDS Air and fuel enter the engine through an intake manifold and exit the engine through the exhaust manifold. Intake manifolds operate cooler than exhaust manifolds and are therefore constructed of nylon-reinforced plastic or aluminum. Exhaust manifolds must be able to withstand hot exhaust gases, so most are constructed from cast iron or steel tubing.
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COOLING SYSTEM All engines must have a cooling system to control engine temperatures. While some older engines were air cooled, all current production passenger vehicle engines are cooled by circulating antifreeze coolant through passages in the block and cylinder head. The coolant picks up the heat from the engine and after the thermostat opens, the water pump circulates the coolant through the radiator where the excess heat is released to the outside air, cooling the coolant. The coolant is continuously circulated through the cooling system and the temperature is controlled by the thermostat. SEE FIGURE 18–3.
LUBRICATION SYSTEM
All engines contain moving and sliding parts that must be kept lubricated to reduce wear and friction. The oil pan, bolted to the bottom of the engine block, holds 4 to 7 quarts (4 to 7 liters) of oil. An oil pump, which is driven by the engine, forces the oil through the oil filter and then into passages in the crankshaft and block. These passages are called oil galleries. The oil is also forced up to the valves and then falls down through openings in the cylinder head and block, then back into the oil pan. SEE FIGURE 18–4.
FUEL SYSTEM AND IGNITION SYSTEM
All engines require both a fuel system to supply fuel to the cylinders and an ignition system to ignite the air-fuel mixture in the cylinders. The fuel system includes the following components.
FIGURE 18–3 The coolant temperature is controlled by the thermostat, which opens and allows coolant to flow to the radiator when the temperature reaches the rating temperature of the thermostat.
Fuel tank, where fuel is stored and where most fuel pumps are located
Fuel filter and lines, which transfer the fuel for the fuel tank to the engine
Fuel injectors, which spray fuel into the intake manifold or directly into the cylinder, depending on the type of system used
The ignition system is designed to take 12 volts from the battery and convert it to 5,000 to 40,000 volts needed to jump the gap of a spark plug. Spark plugs are threaded into the cylinder head of each cylinder, and when the spark occurs, it ignites the air-fuel mixture in the cylinder creating pressure and forcing the piston down in the cylinder. The following components are part of the ignition system.
FIGURE 18–4 A typical lubrication system, showing the oil pan, oil pump, oil filter, and oil passages.
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Spark plugs. Provide an air gap inside the cylinder where a spark occurs to start combustion
Sensor(s). Includes crankshaft position (CKP) and camshaft position (CMP) sensors, used by the powertrain control module (PCM) to trigger the ignition coil(s) and the fuel injectors
Ignition coils. Increase battery voltage to 5,000 to 40,000 volts
Ignition control module (ICM). Controls when the spark plug fires
Associated wiring. Electrically connects the battery, ICM, coil, and spark plugs
FOUR-STROKE CYCLE OPERATION
This sequence repeats as the engine rotates. To stop the engine, the electricity to the ignition system is shut off by the ignition switch, which stops the spark to the spark plugs. The combustion pressure developed in the combustion chamber at the correct time will push the piston downward to rotate the crankshaft.
THE 720-DEGREE CYCLE Each cycle (four strokes) of events requires that the engine crankshaft make two complete revolutions, or 720 degrees (360 degrees ⫻ 2 ⫽ 720 degrees). Each stroke of the cycle requires that the crankshaft rotate 180 degrees. The greater the number of cylinders, the closer together the power strokes of the individual cylinders will occur. The number of degrees that the crankshaft rotates between power strokes can be expressed as an angle. To find the angle between cylinders of an engine, divide the number of cylinders into 720 degrees. Angle with 3 cylinders: 720/3 ⫽ 240 degrees Angle with 4 cylinders: 720/4 ⫽ 180 degrees Angle with 5 cylinders: 720/5 ⫽ 144 degrees
PRINCIPLES
The first four-stroke cycle engine was developed by a German engineer, Nickolaus Otto, in 1876. Most automotive engines use the four-stroke cycle of events. The process begins by the starter motor rotating the engine until combustion takes place. The four-stroke cycle is repeated for each cylinder of the engine. SEE FIGURE 18–5. A piston that moves up and down, or reciprocates, in a cylinder can be seen in Figure 18–5. The piston is attached to a crankshaft with a connecting rod. This arrangement allows the piston to reciprocate (move up and down) in the cylinder as the crankshaft rotates. SEE FIGURE 18–6.
OPERATION
Engine cycles are identified by the number of piston strokes required to complete the cycle. A piston stroke is a one-way piston movement either from top to bottom or bottom to top of the cylinder. During one stroke, the crankshaft rotates 180 degrees (1/2 revolution). A cycle is a complete series of events that continually repeats. Most automobile engines use a four-stroke cycle.
Intake stroke. The intake valve is open and the piston inside the cylinder travels downward, drawing a mixture of air and fuel into the cylinder. The crankshaft rotates 180 degrees from top dead center (TDC) to bottom dead center (BDC) and the camshaft rotates 90 degrees.
Compression stroke. As the engine continues to rotate, the intake valve closes and the piston moves upward in the cylinder, compressing the air-fuel mixture. The crankshaft rotates 180 degrees from bottom dead center (BDC) to top dead center (TDC) and the camshaft rotates 90 degrees.
Power stroke. When the piston gets near the top of the cylinder, the spark at the spark plug ignites the air-fuel mixture, which forces the piston downward. The crankshaft rotates 180 degrees from top dead center (TDC) to bottom dead center (BDC) and the camshaft rotates 90 degrees.
Exhaust stroke. The engine continues to rotate, and the piston again moves upward in the cylinder. The exhaust valve opens, and the piston forces the residual burned gases out of the exhaust valve and into the exhaust manifold and exhaust system. The crankshaft rotates 180 degrees from bottom dead center (BDC) to top dead center (TDC) and the camshaft rotates 90 degrees.
Angle with 6 cylinders: 720/6 ⫽ 120 degrees Angle with 8 cylinders: 720/8 ⫽ 90 degrees Angle with 10 cylinders: 720/10 ⫽ 72 degrees This means that in a 4-cylinder engine, a power stroke occurs at every 180 degrees of the crankshaft rotation (every 1/2 rotation). A V-8 is a much smoother operating engine because a power stroke occurs twice as often (every 90 degrees of crankshaft rotation).
ENGINE CLASSIFICATION AND CONSTRUCTION Engines are classified by several characteristics, including:
Number of strokes. Most automotive engines use the fourstroke cycle.
Cylinder arrangement. An engine with more cylinders is smoother operating because the power pulses produced by the power strokes are more closely spaced. An inline engine places all cylinders in a straight line. The 4-, 5-, and 6-cylinder engines are commonly manufactured inline engines. A V-type engine, such as a V-6 or V-8, has the number of cylinders split and built into a V shape. SEE FIGURE 18–7. Horizontally opposed 4- and 6-cylinder engines have two banks of cylinders that are horizontal, resulting in a low engine. This style of engine is used in Porsche and Subaru engines, and is often called the boxer or pancake engine design. SEE FIGURE 18–8.
Longitudinal and transverse mounting. Engines may be mounted either parallel with the length of the vehicle (longitudinally) or crosswise (transversely). SEE FIGURES 18–9 AND 18–10. The same engine may be mounted in various vehicles in either direction. NOTE: Although it might be possible to mount an engine in different vehicles both longitudinally and transversely, the engine component parts may not be interchangeable. Differences can include different engine blocks and crankshafts, as well as different water pumps.
Valve and camshaft number and location. The number of valves per cylinder and the number and location of camshafts
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BOTH VALVES CLOSED
INTAKE VALVE INTAKE PORT AIR−FUEL MIXTURE
PISTON DESCENDS, DRAWING FUEL AND AIR INTO THE CYLINDER
PISTON RISES, COMPRESSING THE INTAKE CHARGE
CRANKSHAFT ROTATION CONNECTING ROD
THE INTAKE STROKE
THE COMPRESSION STROKE
SPARK PLUG FIRES
INTAKE VALVE CLOSED
EXHAUST PORT
AIR AND FUEL IGNITE
EXHAUST VALVE OPEN
PISTON FORCED DOWN IN THE CYLINDER BY EXPANDING GASES
THE POWER STROKE
PISTON RISES, FORCING EXHAUST GASES FROM THE CYLINDER
THE EXHAUST STROKE
FIGURE 18–5 The downward movement of the piston draws the air-fuel mixture into the cylinder through the intake valve on the intake stroke. On the compression stroke, the mixture is compressed by the upward movement of the piston with both valves closed. Ignition occurs at the beginning of the power stroke, and combustion drives the piston downward to produce power. On the exhaust stroke, the upward-moving piston forces the burned gases out the open exhaust valve.
are major factors in engine operation. A typical older-model engine uses one intake valve and one exhaust valve per cylinder. Many newer engines use two intake and two exhaust valves per cylinder. The valves are opened by a camshaft. Some engines use one camshaft for the intake valves and a separate camshaft for the exhaust valves. When the camshaft is located in the block, the valves are operated by lifters, pushrods, and rocker arms.
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This type of engine is called:
A pushrod engine
Cam-in-block design
Overhead valve (OHV), because an overhead valve engine has the valves located in the cylinder head ( SEE FIGURE 18–11.)
When one overhead camshaft is used, the design is called a single overhead camshaft (SOHC) design. When two overhead
ENGINE
DIFFERENTIAL
PROPELLER SHAFT OR DRIVESHAFT
REAR AXLES UNIVERSAL JOINTS
TRANSMISSION CLUTCH OR TORQUE CONVERTER
FIGURE 18–9 A longitudinally mounted engine drives the rear wheels through a transmission, driveshaft, and differential assembly. TRANSMISSION AND DIFFERENTIAL
TRANSMISSION WITH THE DIFFERENTIAL BELOW
PISTON
CLUTCH OR TORQUE CONVERTER
CONNECTING ROD HALF SHAFTS
CLUTCH OR TORQUE CONVERTER
HALF SHAFTS TRANSVERSE ENGINE
LONGITUDINAL ENGINE
FIGURE 18–10 Two types of front-engine, front-wheel drive mountings. CRANKSHAFT
FIGURE 18–6 Cutaway of an engine showing the cylinder, piston, connecting rod, and crankshaft.
4 CYLINDER
5 CYLINDER INLINE - TYPE ENGINES
6 CYLINDER
FIGURE 18–11 Cutaway of an overhead valve (OHV) V-8 engine showing the lifters, pushrods, roller rocker arms, and valves.
V-4 ENGINE
V-6 ENGINE V - TYPE ENGINES
camshafts are used, the design is called a double overhead camshaft (DOHC) design. SEE FIGURES 18–12 AND 18–13.
V-8 ENGINE
FIGURE 18–7 Automotive engine cylinder arrangements.
NOTE: A V-type engine uses two banks or rows of cylinders. An SOHC design, therefore, uses two camshafts but only one camshaft per bank (row) of cylinders. A DOHC V-6, therefore, has four camshafts, two for each bank.
CRANKSHAFT PISTON
FIGURE 18–8 A horizontally opposed engine design helps to lower the vehicle’s center of gravity.
Type of fuel. Most engines operate on gasoline, whereas some engines are designed to operate on ethanol (E85), methanol (M85), natural gas, propane, or diesel fuel.
Cooling method. Most engines are liquid cooled, but some older models were air cooled. Air-cooled engines, such as the original VW Beatle, could not meet exhaust emission standards.
Type of induction pressure. If atmospheric air pressure is used to force the air-fuel mixture into the cylinders, the engine is called naturally aspirated. Some engines use a turbocharger or supercharger to force the air-fuel mixture into the cylinder for even greater power.
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CAM FOLLOWER
CAM FOLLOWER
?
FREQUENTLY ASKED QUESTION
What Is a Rotary Engine?
CAMSHAFT
SINGLE OVERHEAD CAMSHAFT CAMSHAFT
LIFTER
CAMSHAFT
A successful alternative engine design is the rotary engine, also called the Wankel engine after its inventor, Felix Heinrich Wankel (1902–1988), a German inventor. The Mazda RX-7 and RX-8 represent the only long-term use of the rotary engine. The rotating combustion chamber engine runs very smoothly, and it produces high power for its size and weight. The basic rotating combustion chamber engine has a triangular-shaped rotor turning in a housing. The housing is in the shape of a geometric figure called a two-lobed epitrochoid. A seal on each corner, or apex, of the rotor is in constant contact with the housing, so the rotor must turn with an eccentric motion. This means that the center of the rotor moves around the center of the engine. The eccentric motion can be seen in FIGURE 18–14.
?
FREQUENTLY ASKED QUESTION
Where Does an Engine Stop? LIFTER
DOUBLE OVERHEAD CAMSHAFT
FIGURE 18–12 SOHC engines usually require additional components, such as a rocker arm, to operate all of the valves. DOHC engines often operate the valves directly.
When the ignition system is turned off, the firing of the spark plugs stops and the engine will rotate until it stops due to the inertia of the rotating parts. The greatest resistance that occurs in the engine happens during the compression stroke. It has been determined that an engine usually stops when one of the cylinders is about 70 degrees before top dead center (BTDC) on the compression stroke with a variation of plus or minus 10 degrees. This explains why technicians discover that the starter ring gear is worn at two locations on a 4-cylinder engine. The engine stops at one of the two possible places depending on which cylinder is on the compression stroke.
ENGINE ROTATION DIRECTION The SAE standard for automotive engine rotation is counterclockwise (CCW) as viewed from the flywheel end (clockwise as viewed from the front of the engine). The flywheel end of the engine is the end to which the power is applied to drive the vehicle. This is called the principal end of the engine. The nonprincipal end of the engine is opposite the principal end and is generally referred to as the front of the engine, where the accessory belts are used. SEE FIGURE 18–15. Therefore, in most rear-wheel-drive vehicles, the engine is mounted longitudinally with the principal end at the rear of the engine. Most transversely mounted engines also adhere to the same standard for direction of rotation. Many Honda engines, and some marine applications, may differ from this standard.
ENGINE MEASUREMENT
FIGURE 18–13 A DOHC engine uses a camshaft for the intake valves and a separate camshaft for the exhaust valves in each cylinder head.
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BORE The diameter of a cylinder is called the bore. The larger the bore, the greater the area on which the gases have to work. Pressure is measured in units, such as pounds per square inch (PSI). The greater the area (in square inches), the higher the force exerted by the pistons to rotate the crankshaft. SEE FIGURE 18–16.
ECCENTRIC GEAR ON SHAFT
COMPRESSION
INTAKE
INTAKE PORT
EXHAUST PORT
ROTOR
INTAKE
COMPRESSION
SPARK PLUGS
MAXIMUM COMPRESSION AND FIRING
POWER
EXHAUST
FIGURE 18–14 A rotary engine operates on the four-stroke cycle but uses a rotor instead of a piston and crankshaft to achieve intake, compression, power, and exhaust stroke.
DIRECTION OF ROTATION FLEX-PLATE (DRIVE-PLATE) PRINCIPAL END
STROKE
BORE
PISTON DISPLACEMENT
NONPRINCIPAL END
DIRECTION OF ROTATION
FIGURE 18–15 Inline 4-cylinder engine showing principal and nonprincipal ends. Normal direction of rotation is clockwise (CW) as viewed from the front or accessory belt (nonprincipal) end.
BOTTOM DEAD CENTER
TOP DEAD CENTER
FIGURE 18–16 The bore and stroke of pistons are used to calculate an engine’s displacement.
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TECH TIP How Fast Can an Engine Rotate? Most passenger vehicle engines are designed to rotate at low speed for the following reasons. • Maximum efficiency is achieved at low engine speed. A diesel engine used in a large ship, for example, will rotate at about 100 RPM for maximum efficiency. • Piston ring friction is the highest point of friction in the engine. The slower the engine speed, the less loss to friction from the piston rings.
CENTER LINE ROD BEARING JOURNAL CENTER LINE MAIN BEARING JOURNAL
However, horsepower is what is needed to get a vehicle down the road quickly. Horsepower is torque times engine speed divided by 5,252. Therefore, a high engine speed usually indicates a high horsepower. For example, a Formula 1 race car is limited to 2.4 liter V-8 but uses a 1.6 in. (40 mm) stroke. This extremely short stroke means that the engine can easily achieve the upper limit allowed by the rules of 18,000 RPM while producing over 700 horsepower. The larger the engine, the more power the engine is capable of producing. Several sayings are often quoted about engine size:
FIGURE 18–17 The distance between the centerline of the main bearing journal and the centerline of the connecting rod journal determines the stroke of the engine. This photo is a little unusual because it shows a V-6 with a splayed crankshaft used to even out the impulses on a 90-degree, V-6 engine design.
STROKE The stroke of an engine is the distance the piston travels from top dead center (TDC) to bottom dead center (BDC). This distance is determined by the throw of the crankshaft. The throw is the distance from the centerline of the crankshaft to the centerline of the crankshaft rod journal. The throw is one-half of the stroke. SEE FIGURE 18–17. The longer this distance is, the greater the amount of air-fuel mixture that can be drawn into the cylinder. The more air-fuel mixture inside the cylinder, the more force will result when the mixture is ignited.
“There is no substitute for cubic inches.” “There is no replacement for displacement.” Although a large engine generally uses more fuel, making an engine larger is often the easiest way to increase power.
NOTE: Changing the connecting rod length does not change the stroke of an engine. Changing the connecting rod only changes the position of the piston in the cylinder. Only the crankshaft determines the stroke of an engine.
The formula is: Cubic inch displacement ⴝ (pi) ⴛ R2 ⴛ Stroke ⴛ Number of cylinders R ⫽ Radius of the cylinder or one-half of the bore. The πR2 part is the formula for the area of a circle.
DISPLACEMENT
Engine size is described as displacement. Displacement is the cubic inch (cu. in.) or cubic centimeter (cc) volume displaced or how much air is moved by all of the pistons. A liter (L) is equal to 1,000 cubic centimeters; therefore, most engines today are identified by their displacement in liters.
Bore ⫽ 4.000 in.
Stroke ⫽ 3.000 in.
1 L ⫽ 61 cu. in.
⫽ 3.14
R ⫽ 2 inches
R2 ⫽ 4 (22 or 2 ⫻ 2)
CONVERSION To convert cubic inches to liters, divide cubic inches by 61.02. Liters 5
1 L ⫽ 1,000 cc 1 cu. in. ⫽ 16.4 cc
Applying the formula to a 6-cylinder engine:
Cubic inches 61.02
To convert liters into cubic inches, multiply by 61.02. Cubic inches ⴝ Liters ⴛ 61.02
CALCULATING CUBIC INCH DISPLACEMENT The formula to calculate the displacement of an engine is basically the formula for determining the volume of a cylinder multiplied by the number of cylinders.
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Cubic inches ⫽ 3.14 ⫻ 4 (R2) ⫻ 3 (stroke) ⫻ 6 (number of cylinders). Cubic inches ⫽ 226 cubic inches Because 1 cubic inch equals 16.4 cubic centimeters, this engine displacement equals 3,706 cubic centimeters or, rounded to 3,700 cubic centimeters, 3.7 liters. SEE CHART 18–1 for an example of engine sizes for a variety of bore and stroke measurements.
ENGINE SIZE CONVERSION Many vehicle manufacturers will round the displacement so the calculated cubic inch displacement may not agree with the published displacement value. SEE CHART 18–2.
V-8 ENGINE STROKE
3.50
3.75
3.875
4.00
4.125
BORE
Cu. In.
Cu. In.
Cu. In.
Cu. In.
Cu. In.
3.00
199
212
219
226
233
3.125
214
229
237
244
252
3.250
232
249
257
265
274
3.375
251
269
277
286
295
3.500
269
288
298
308
317
3.625
288
309
319
330
339
3.750
309
332
343
354
365
3.875
331
354
366
378
390
4.00
352
377
389
402
414
4.125
373
399
413
426
439
STROKE
3.50
3.75
3.875
4.00
4.125
BORE
Cu. In.
Cu. In.
Cu. In.
Cu. In.
Cu. In.
3.00
148
159
164
169
175
3.125
161
172
178
184
190
3.250
174
186
193
199
205
3.375
188
201
208
215
222
3.500
202
216
223
228
238
3.625
216
232
239
247
255
3.750
232
249
257
265
273
3.875
248
266
275
283
292
4.00
264
283
292
301
311
4.125
280
299
309
319
329
STROKE
3.50
3.75
3.875
4.00
4.125
BORE
Cu. In.
Cu. In.
Cu. In.
Cu. In.
Cu. In.
3.00
99
106
110
113
117
3.125
107
115
119
123
126
3.250
116
124
129
133
137
3.375
125
134
139
143
148
3.500
135
144
149
152
159
3.625
144
158
160
165
170
3.750
155
166
171
177
182
3.875
165
177
183
189
195
4.00
176
188
195
201
207
4.125
186
200
206
213
220
6-CYLINDER ENGINE
4-CYLINDER ENGINE
CHART 18–1 To find the cubic inch displacement, find the bore that is closest to the actual value, then go across to the closest stroke value.
COMPRESSION RATIO DEFINITION
Compression ratio (CR) is the ratio of the difference in the cylinder volume when the piston is at the bottom of the stroke to the volume in the cylinder above the piston when the piston is at the top of the stroke. The compression ratio of an engine is an important consideration when rebuilding or repairing an engine. SEE FIGURE 18–18.
If Compression Is Lower
If Compression Is Higher
Lower power
Higher power possible
Poorer fuel economy
Better fuel economy possible
Easier engine cranking
Harder to crank engine, especially when hot
More advanced ignition timing possible without spark knock (detonation)
Less ignition timing required to prevent spark knock (detonation)
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LITERS TO CUBIC INCHES LITERS
CUBIC INCHES
LITERS
CUBIC INCHES
LITERS
CUBIC INCHES
1.0
61
3.2
196
5.4
330
1.3
79
3.3
200 / 201
5.7
350
1.4
85
3.4
204
5.8
351
1.5
91
3.5
215
6.0
366 / 368
1.6
97 / 98
3.7
225
6.1
370
1.7
105
3.8
229 / 231 / 232
6.2
381
1.8
107 / 110 / 112
3.9
239 / 240
6.4
389 / 390 / 391
1.9
116
4.0
241 / 244
6.5
396
2.0
121 / 122
4.1
250 / 252
6.6
400
2.1
128
4.2
255 / 258
6.9
420
2.2
132 / 133 / 134 / 135
4.3
260 / 262 / 265
7.0
425 / 427 / 428 / 429
2.3
138 / 140
4.4
267
7.2
440
2.4
149
4.5
273
7.3
445
2.5
150 / 153
4.6
280 / 281
7.4
454
2.6
156 / 159
4.8
292
7.5
460
2.8
171 / 173
4.9
300 / 301
7.8
475 / 477
2.9
177
5.0
302 / 304 / 305 / 307
8.0
488
3.0
181 / 182 / 183
5.2
318
8.8
534
3.1
191
5.3
327
CHART 18–2 Liters to cubic inches is often not exact and can result in representing several different engine sizes based on their advertised size in liters.
CLEARANCE VOLUME
COMPRESSION RATIO = 8:1
COMBUSTION CHAMBER VOLUME DECK HEIGHT
CYLINDER VOLUME
1 2 3 4 5 6 7 8
PISTON TOP AT TDC
STROKE
PISTON DISPLACEMENT
COMPRESSED HEAD GASKET 0.020 INCH
PISTON TOP AT BDC
BOTTOM DEAD CENTER
TOP DEAD CENTER
FIGURE 18–18 Compression ratio is the ratio of the total cylinder volume (when the piston is at the bottom of its stroke) to the clearance volume (when the piston is at the top of its stroke).
CALCULATING COMPRESSION RATIO
The compression
ratio (CR) calculation uses the formula: CR 5
Volume in cylinder with piston at bottom of cylinder Volume in cylinder with piston at top center
SEE FIGURE 18–19.
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FIGURE 18–19 Combustion chamber volume is the volume above the piston when the piston is at top dead center.
For example: What is the compression ratio of an engine with 50.3 cu. in. displacement in one cylinder and a combustion chamber volume of 6.7 cu. in.? CR 5
57.0 50.3 1 6.7cu. in. 5 5 8.5 6.7 cu. in. 6.7
?
1 FOOT
FREQUENTLY ASKED QUESTION
Is Torque ft-lb or lb-ft? The definition of torque is a force (lb) applied to an object times the distance from that object (ft). Therefore, based on the definition of the term, torque should be:
10 POUNDS
lb-ft (a force times a distance) Newton-meter (N-m) (a force times a distance) FIGURE 18–20 Torque is a twisting force equal to the distance from the pivot point times the force applied expressed in units called pound-feet (lb-ft) or newton-meters (N-m).
CHANGING COMPRESSION RATIO
Any time an engine is modified, the compression ratio should be checked to make sure it is either the same as it was originally or has been changed to match the diesel compression ratio. Factors that can affect compression ratio include:
Head gasket thickness. A thicker than stock gasket will decrease the compression ratio and a thinner than stock gasket will increase the compression ratio.
Increasing the cylinder size. If the bore or stroke is increased, a greater amount of air will be compressed into the combustion chamber, which will increase the compression ratio.
TORQUE AND HORSEPOWER DEFINITION OF TORQUE
Torque is the term used to describe a rotating force that may or may not result in motion. Torque is measured as the amount of force multiplied by the length of the lever through which it acts. If you use a 1 ft long wrench to apply 10 pounds (lb) of force to the end of the wrench to turn a bolt, then you are exerting 10 pound-feet (lb-ft) of torque. SEE FIGURE 18–20. Torque is the twisting force measured at the end of the crankshaft and measured on a dynamometer. Engine torque is always expressed at a specific engine speed (RPM) or range of engine speeds where the torque is at the maximum. For example, an engine may be listed as producing 275 lb-ft @ 2,400 RPM. The metric unit for torque is newton-meters, because the newton is the metric unit for force and the distance is expressed in meters. 1 pound-foot ⫽ 1.3558 newton-meters 1 newton-meter ⫽ 0.7376 pound-foot
DEFINITION OF POWER
The term power means the rate of doing work. Power equals work divided by time. Work is achieved when a certain amount of mass (weight) is moved a certain distance by a force. If the object is moved in 10 seconds
However, torque is commonly labeled, even on some torque wrenches as ft-lb.
TECH TIP Quick-and-Easy Engine Efficiency Check A good, efficient engine is able to produce a lot of power from little displacement. A common rule of thumb is that an engine is efficient if it can produce 1 horsepower per cubic inch of displacement. Many engines today are capable of this feat, such as the following: Ford: 4.6 liter V-8 (281 cu. in.): 305 hp Chevrolet: 3.0 liter V-6 (207 cu. in.): 210 hp Chrysler: 3.5 liter V-6 (214 cu. in.): 214 hp Acura: 3.2 liter V-6 (195 cu. in.): 260 hp An engine is very powerful for its size if it can produce 100 hp per liter. This efficiency goal is harder to accomplish. Most factory stock engines that can achieve this feat are supercharged or turbocharged.
or 10 minutes does not make a difference in the amount of work accomplished, but it does affect the amount of power needed. Power is expressed in units of foot-pounds per minute and power also includes the engine speed (RPM) where the maximum power is achieved. For example, an engine may be listed as producing 280 hp @ 4400 RPM.
HORSEPOWER AND ALTITUDE
Because the density of the air is lower at high altitude, the power that a normal engine can develop is greatly reduced at high altitude. According to SAE conversion factors, a nonsupercharged or nonturbocharged engine loses about 3% of its power for every 1,000 ft (300 m) of altitude. Therefore, an engine that develops 200 brake horsepower at sea level will only produce about 116 brake horsepower at the top of Pike’s Peak in Colorado at 14,110 ft (4,300 m) (3% ⫻ 14 – 42%). Supercharged and turbocharged engines are not as greatly affected by altitude as normally aspirated engines, which are those engines that breathe air at normal atmospheric pressure.
REVIEW QUESTIONS 1. What are the strokes of a four stroke cycle?
2. If an engine at sea level produces 100 hp, how many horsepower would it develop at 6,000 ft of altitude?
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CHAPTER QUIZ 1. All overhead valve engines ______________. a. Use an overhead camshaft b. Have the valves located in the cylinder head c. Operate by the two-stroke cycle d. Use the camshaft to close the valves 2. An SOHC V-8 engine has how many camshafts? a. One c. Three b. Two d. Four 3. The coolant flow through the radiator is controlled by the ______________. a. Size of the passages in the block b. Thermostat c. Cooling fan(s) d. Water pump 4. Torque is expressed in units of ______________. a. Pound-feet b. Foot-pounds c. Foot-pounds per minute d. Pound-feet per second 5. Horsepower is expressed in units of ______________. a. Pound-feet c. Foot-pounds per minute b. Foot-pounds d. Pound-feet per second
chapter
19
6. A normally aspirated automobile engine ______________ power per 1,000 ft of altitude. a. 1% c. 5% b. 3% d. 6%
loses
about
7. One cylinder of an automotive four-stroke cycle engine completes a cycle every ______________. a. 90 degrees c. 360 degrees b. 180 degrees d. 720 degrees 8. How many rotations of the crankshaft are required to complete each stroke of a four-stroke cycle engine? a. One-fourth c. One b. One-half d. Two 9. A rotating force is called ______________. a. Horsepower c. Combustion pressure b. Torque d. Eccentric movement 10. Technician A says that a crankshaft determines the stroke of an engine. Technician B says that the length of the connecting rod determines the stroke of an engine. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
DIESEL ENGINE OPERATION AND DIAGNOSIS
OBJECTIVES: After studying Chapter 19, the reader should be able to: • Prepare for ASE Engine Performance (A8) certification test content area “C” (Fuel, Air Induction, and Exhaust Systems Diagnosis and Repair). • Explain how a diesel engine works. • Describe the difference between direct injection (DI) and indirect injection (IDI) diesel engines. • List the parts of the typical diesel engine fuel system. • Explain how glow plugs work. • List the advantages and disadvantages of a diesel engine. KEY TERMS: Diesel exhaust fluid (DEF) 170 • Diesel exhaust particulate filter (DPF) 169 • Diesel oxidation catalyst (DOC) 168 • Differential pressure sensor (DPS) 169 • Direct injection (DI) 160 • Glow plug 164 • Heat of compression 158 • High-pressure common rail (HPCR) 162 • Hydraulic electronic unit injection (HEUI) 162 • Indirect injection (IDI) 160 • Injection pump 158 • Lift pump 161 • Opacity 174 • Pop tester 173 • Particulate matter (PM) 168 • Regeneration 169 • Selective catalytic reduction (SCR) 170 • Soot 168 • Urea 170 • Water-fuel separator 161
DIESEL ENGINES FUNDAMENTALS In 1892, a German engineer named Rudolf Diesel perfected the compression ignition engine that bears his name. The diesel engine uses heat created by compression to ignite the fuel, so it requires no spark ignition system. The diesel engine requires compression ratios of 16:1 and higher. Incoming air is compressed until its temperature reaches
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about 1,000°F (540°C). This is called heat of compression. As the piston reaches the top of its compression stroke, fuel is injected into the cylinder, where it is ignited by the hot air. SEE FIGURE 19–1. As the fuel burns, it expands and produces power. Because of the very high compression and torque output of a diesel engine, it is made heavier and stronger than the same size gasoline-powered engine. A diesel engine uses a fuel system with a precision injection pump and individual fuel injectors. The pump delivers fuel to the injectors at a high pressure and at timed intervals. Each injector sprays
INJECTOR EXHAUST VALVE
AIR INTAKE VALVE
FIGURE 19–1 Diesel combustion occurs when fuel is injected into the hot, highly compressed air in the cylinder.
INJECTOR LINE
RETURN LINE INJECTOR
SYSTEM OR COMPONENT
FUEL INJECTION PUMP
FUEL TANK
INLET LINE
FIGURE 19–3 A Cummins diesel engine as found in a Dodge pickup truck. A high-pressure pump (up to 30,000 PSI) is used to supply diesel fuel to this common rail, which has tubes running to each injector. Note the thick cylinder walls and heavy-duty construction.
TRANSFER PUMP
DIESEL ENGINE
GASOLINE ENGINE
Block
Cast iron and heavy ( SEE FIGURE 19–3.)
Cast iron or aluminum and as light as possible
Cylinder head
Cast iron or aluminum
Cast iron or aluminum
Compression ratio
17:1 to 25:1
8:1 to 12:1
Peak engine speed
2000 to 2500 RPM
5000 to 8000 RPM
Pistons
Aluminum with combustion pockets and heavy-duty connecting rods ( SEE FIGURE 19–4.)
Aluminum, usually flat top or with valve relief but no combustion pockets
SUPPLY LINE
FIGURE 19–2 A typical injector pump type of automotive diesel fuel–injection system. CHART 19–1
Comparison between a typical gasoline and a diesel engine. fuel into the combustion chamber at the precise moment required for efficient combustion. SEE FIGURE 19–2.
ADVANTAGES AND DISADVANTAGES
A diesel engine has several advantages compared to a similar size gasoline-powered engine, including: 1. More torque output 2. Greater fuel economy 3. Long service life
A diesel engine has several disadvantages compared to a similar size gasoline-powered engine, including: 1. Engine noise, especially when cold and/or at idle speed 2. Exhaust smell 3. Cold weather startability 4. Vacuum pump that is needed to supply the vacuum needs of the heat, ventilation, and air-conditioning system 5. Heavier than a gasoline engine
6. Fuel availability 7. Extra cost compared to a gasoline engine
CONSTRUCTION Diesel engines must be constructed heavier than gasoline engines because of the tremendous pressures that are created in the cylinders during operation. SEE CHART 19–1. The torque output of a diesel engine is often double or more than the same size gasoline-powered engines. AIR-FUEL RATIOS
In a diesel engine, air is not controlled by a throttle as in a gasoline engine. Instead, the amount of fuel injected is varied to control power and speed. The air-fuel mixture of a diesel can vary from as lean as 85:1 at idle to as rich as 20:1 at full load. This higher air-fuel ratio and the increased compression pressures make the diesel more fuel efficient than a gasoline engine, in part because diesel engines do not suffer from throttling losses. Throttling losses involve the power needed in a gasoline engine to draw air past a closed or partially closed throttle.
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FUEL INJECTOR INTAKE VALVE
CYLINDER HEAD
PISTON
FIGURE 19–4 A rod/piston assembly from a 5.9 liter Cummins diesel engine used in a Dodge pickup truck.
PRECHAMBER
FUEL INJECTOR INTAKE VALVE
PISTON
GLOW PLUG
FIGURE 19–5 An indirect injection diesel engine uses a prechamber and a glow plug.
In a gasoline engine, the speed and power are controlled by the throttle valve, which controls the amount of air entering the engine. Adding more fuel to the cylinders of a gasoline engine without adding more air (oxygen) will not increase the speed or power of the engine. In a diesel engine, speed and power are not controlled by the amount of air entering the cylinders because the engine air intake is always wide open. Therefore, the engine always has enough oxygen to burn the fuel in the cylinder and will increase speed (and power) when additional fuel is supplied.
FIGURE 19–6 A direct injection diesel engine injects the fuel directly into the combustion chamber. Many designs do not use a glow plug.
All indirect diesel injection engines require the use of a glow plug which is an electrical heater that helps start the combustion process. In a direct injection (abbreviated DI) diesel engine, fuel is injected directly into the cylinder. The piston incorporates a depression where initial combustion takes place. Direct injection diesel engines are generally more efficient than indirect injection engines, but have a tendency to produce greater amounts of noise. SEE FIGURE 19–6. While some direct injection diesel engines use glow plugs to help cold starting and to reduce emissions, many direct injection diesel engines do not use glow plugs.
DIESEL FUEL IGNITION
Ignition occurs in a diesel engine by injecting fuel into the air charge, which has been heated by compression to a temperature greater than the ignition point of the fuel or about 1,000°F (538°C). The chemical reaction of burning the fuel creates heat, which causes the gases to expand, forcing the piston to rotate the crankshaft. A four-stroke diesel engine requires two rotations of the crankshaft to complete one cycle.
On the intake stroke, the piston passes TDC, the intake valve(s) opens, and filtered air enters the cylinder, while the exhaust valve(s) remains open for a few degrees to allow all of the exhaust gases to escape from the previous combustion event.
On the compression stroke, after the piston passes BDC, the intake valve(s) closes and the piston travels up to TDC (completion of the first crankshaft rotation).
On the power stroke, the piston nears TDC on the compression stroke and diesel fuel is injected into the cylinder by the injectors. The ignition of the fuel does not start immediately but the heat of compression starts the combustion phases in the cylinder. During this power stroke, the piston passes TDC and the expanding gases force the piston down, rotating the crankshaft.
On the exhaust stroke, as the piston passes BDC, the exhaust valve(s) opens and the exhaust gases start to flow out of the cylinder. This continues as the piston travels up to TDC, pumping the spent gases out of the cylinder. At TDC, the second crankshaft rotation is complete.
NOTE: Many newer diesel engines are equipped with a throttle valve. This valve is used by the emission control system and is not designed to control the speed of the engine.
INDIRECT AND DIRECT INJECTION
In an indirect injection (abbreviated IDI) diesel engine, fuel is injected into a small prechamber, which is connected to the cylinder by a narrow opening. The initial combustion takes place in this prechamber. This has the effect of slowing the rate of combustion, which tends to reduce noise. SEE FIGURE 19–5.
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THREE PHASES OF COMBUSTION There are three distinct phases or parts to the combustion in a diesel engine. 1. Ignition delay. Near the end of the compression stroke, fuel injection begins, but ignition does not begin immediately. This period is called ignition delay. 2. Rapid combustion. This phase of combustion occurs when the fuel first starts to burn, creating a sudden rise in cylinder pressure. It is this sudden and rapid rise in combustion chamber pressure that causes the characteristic diesel engine knock. 3. Controlled combustion. After the rapid combustion occurs, the rest of the fuel in the combustion chamber begins to burn and injection continues. This process occurs in an area near the injector that contains fuel surrounded by air. This fuel burns as it mixes with the air.
FIGURE 19–7 A fuel temperature sensor is being tested using an ice bath.
FUEL TANK AND LIFT PUMP PARTS INVOLVED
A fuel tank used on a vehicle equipped with a diesel engine differs from the one used with a gasoline engine in the following ways.
The filler neck is larger for diesel fuel. The nozzle size is 15/16 in. (24 mm) instead of 13/16 in. (21 mm) for gasoline filler necks. Truck stop diesel nozzles for large over-the-road trucks are usually larger, 1.25 in. or 1.5 in. (32 mm or 38 mm) to allow for faster fueling of large-capacity fuel tanks. There are no evaporative emission control devices or a charcoal (carbon) canister. Diesel fuel is not as volatile as gasoline and, therefore, diesel vehicles do not have evaporative emission control devices.
The diesel fuel is usually drawn from the fuel tank by a separate pump, called a lift pump and delivers the fuel to the injection pump. Between the fuel tank and the lift pump is a water-fuel separator. Water is heavier than diesel fuel and sinks to the bottom of the separator. Part of normal routine maintenance on a vehicle equipped with a diesel engine is to drain the water from the water-fuel separator. A float is often used inside the separator, which is connected to a warning light on the dash that lights if the water reaches a level where it needs to be drained. The water separator is often part of the fuel filter assembly. Both the fuel filter and the water separator are common maintenance items.
FUEL INJECTOR LINES FUEL FILTER
FIGURE 19–8 A typical distributor-type diesel injection pump showing the pump, lines, and fuel filter.
INJECTION PUMP NEED FOR HIGH-PRESSURE FUEL PUMP
A diesel engine injection pump is used to increase the pressure of the diesel fuel from very low values from the lift pump to the extremely high pressures needed for injection.
NOTE: Water can cause corrosive damage and wear to diesel engine parts because it is not a good lubricant. Water cannot be atomized by a diesel fuel injector nozzle and will often “blow out” the nozzle tip. Many diesel engines also use a fuel temperature sensor. The computer uses this information to adjust fuel delivery based on the density of the fuel. SEE FIGURE 19–7.
The lift pump is a low-pressure, high-volume pump. The high-pressure injection pump is a high-pressure, low-volume pump.
Injection pumps are usually driven by a gear off the camshaft at the front of the engine. As the injection pump shaft rotates, the diesel fuel is fed from a fill port to a high-pressure chamber. If a distributortype injection pump is used, the fuel is forced out of the injection port to the correct injector nozzle through the high-pressure line. SEE FIGURE 19–8.
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FUEL INJECTION PUMP INJECTION TIMING STEPPER MOTOR
RETURN LINE
EACH OF THE HIGH PRESSURE LINES MUST BE OF EQUAL LENGTH
PIVOT ADVANCE PISTON
FUEL FILTER
ADVANCE
RETARD
LIFT PUMP
FUEL LEVEL SENSOR
INJECTOR
FUEL TANK
FIGURE 19–9 A schematic of Standadyne diesel fuel–injection pump assembly showing all of the related components.
NOTE: Because of the very tight tolerances in a diesel engine, the smallest amount of dirt can cause excessive damage to the engine and to the fuel-injection system.
DISTRIBUTOR INJECTION PUMP
A distributor diesel injection pump is a high-pressure pump assembly with lines leading to each individual injector. The high-pressure lines between the distributor and the injectors must be the exact same length to ensure proper injection timing. The high-pressure fuel causes the injectors to open. Due to the internal friction of the lines, there is a slight delay before fuel pressure opens the injector nozzle. The injection pump itself creates the injection advance needed for engine speeds above idle often by using a stepper motor attached to the advance piston, and the fuel is then discharged into the lines. SEE FIGURE 19–9. NOTE: The lines expand some during an injection event. This is how timing checks are performed. The pulsing of the injector line is picked up by a probe used to detect the injection event similar to a timing light used to detect a spark on a gasoline engine.
HIGH-PRESSURE COMMON RAIL Newer diesel engines use a fuel delivery system referred to as a high-pressure common rail (HPCR) design. Diesel fuel under high pressure, over 20,000 PSI
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(138,000 kPa), is applied to the injectors, which are opened by a solenoid controlled by the computer. Because the injectors are computer controlled, the combustion process can be precisely controlled to provide maximum engine efficiency with the lowest possible noise and exhaust emissions. SEE FIGURE 19–10.
HEUI SYSTEM PRINCIPLES OF OPERATION
Ford 7.3 and 6.0 liter (and Navistar) diesels use a system called a hydraulic electronic unit injection system, or HEUI system. The components used include:
High-pressure engine oil pump and reservoir
Pressure regulator for the engine oil
Passages in the cylinder head for flow of fuel to the injectors
OPERATION The engine oil is pressurized to provide an opening pressure strong enough to overcome the fuel pressure when the solenoid is commanded to open by the PCM. The system functions as follows:
Fuel is drawn from the tank by the tandem fuel pump, which circulates fuel at low pressure through the fuel filter/water
COMMON RAIL (LEFT BANK)
PRESSURE LIMITING VALVE RAIL PRESSURE COMMON RAIL SENSOR (RIGHT BANK)
HIGH PRESSURE PUMP
SENSORS ACTUATORS
FILTER WITH WATER SEPARATOR AND INTEGRATED HAND PUMP
ELECTRONIC CONTROL MODULE
TANK HIGH PRESSURE LOW PRESSURE
FIGURE 19–10 Overview of a computer-controlled high-pressure common rail V-8 diesel engine.
TECH TIP Change Oil Regularly in a Ford Diesel Engine
O-RING GROOVE
Ford 7.3 and 6.0 liter diesel engines pump unfiltered oil from the sump to the high-pressure oil pump and then to the injectors. This means that not changing oil regularly can contribute to accumulation of dirt in the engine and will subject the fuel injectors to wear and potential damage as particles suspended in the oil get forced into the injectors.
separator/fuel heater bowl and then fuel is directed back to the fuel pump where fuel is pumped at high pressure into the cylinder head fuel galleries.
The injectors, which are hydraulically actuated by engine oil pressure from the high-pressure oil pump, are then fired by the powertrain control module (PCM). The control system for the fuel injectors is the PCM, and the injectors are fired based on sensor inputs received by the PCM. SEE FIGURE 19–11.
HEUI injectors rely on O-rings to keep fuel and oil from mixing or escaping, causing performance problems or engine damage. HEUI injectors use five O-rings. The three external O-rings should be replaced with updated O-rings if they fail. The two internal O-rings are not replaceable and if these fail, the injector(s) must be replaced. The most common symptoms of injector O-ring trouble include:
Oil getting in the fuel
The fuel filter element turning black
FIGURE 19–11 A HEUI injector from a Ford PowerStroke diesel engine. The O-ring grooves indicate the location of the O-rings that seal the fuel section of the injector from coolant and from the engine oil.
Long cranking times before starting
Sluggish performance
Reduction in power
Increased oil consumption (This often accompanies O-ring problems or any fault that lets fuel in the oil.)
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TECH TIP Never Allow a Diesel Engine to Run Out of Fuel If a gasoline-powered vehicle runs out of gasoline, it is an inconvenience and a possible additional expense to get some gasoline. However, if a vehicle equipped with a diesel engine runs out of fuel, it can be a major concern. Besides adding diesel fuel to the tank, the other problem is getting all of the air out of the pump, lines, and injectors so the engine will operate correctly. The procedure usually involves cranking the engine long enough to get liquid diesel fuel back into the system, but at the same time keeping cranking time short enough to avoid overheating the starter. Consult service information for the exact service procedure if the diesel engine is run out of fuel. NOTE: Some diesel engines, such as the General Motors Duramax V-8, are equipped with a priming pump located under the hood on top of the fuel filter. Pushing down and releasing the priming pump with a vent valve open will purge any trapped air from the system. Always follow the vehicle manufacturer’s instructions.
FIGURE 19–12 Typical computer-controlled diesel engine fuel injectors.
VALVE SPRING ELECTROMAGNETIC COIL PILOT NEEDLE
DIESEL INJECTOR NOZZLES
FUEL RETURN LINE
Heat shield. This is the outer shell of the injector nozzle and may have external threads where it seals in the cylinder head.
Injector body. This is the inner part of the nozzle and contains the injector needle valve and spring, and threads into the outer heat shield.
Diesel injector needle valve. This precision machined valve and the tip of the needle seal against the injector body when it is closed. When the valve is open, diesel fuel is sprayed into the combustion chamber. This passage is controlled by a computer-controlled solenoid on diesel engines equipped with computer-controlled injection. Injector pressure chamber. The pressure chamber is a machined cavity in the injector body around the tip of the injector needle. Injection pump pressure forces fuel into this chamber, forcing the needle valve open.
BALL DRAIN ORIFICE HIGH-PRESSURE CONNECTION
PARTS INVOLVED Diesel injector nozzles are spring-loaded closed valves that spray fuel directly into the combustion chamber or precombustion chamber when the injector is opened. Injector nozzles are threaded or clamped into the cylinder head, one for each cylinder, and are replaceable as an assembly. The tip of the injector nozzle has many holes to deliver an atomized spray of diesel fuel into the cylinder. Parts of a diesel injector nozzle include:
RETURN SPRING
SERVO-PISTON NOZZLE SPRING PRESSURE PIN
NOZZLE NEEDLE
INJECTION NOZZLE
FIGURE 19–13 A Duramax injector showing all the internal parts.
needle valve return spring and forcing the needle valve open. When the needle valve opens, diesel fuel is discharged into the combustion chamber in a hollow cone spray pattern. Any fuel that leaks past the needle valve returns to the fuel tank through a return passage and line. SEE FIGURE 19–13.
GLOW PLUGS
DIESEL INJECTOR NOZZLE OPERATION
The electric solenoid attached to the injector nozzle is computer controlled and opens to allow fuel to flow into the injector pressure chamber. SEE FIGURE 19–12. The fuel flows down through a fuel passage in the injector body and into the pressure chamber. The high fuel pressure in the pressure chamber forces the needle valve upward, compressing the
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PURPOSE AND FUNCTION
Glow plugs are always used in diesel engines equipped with a precombustion chamber and may be used in direct injection diesel engines to aid starting. A glow plug is a heating element that uses 12 volts from the battery and aids in the starting of a cold engine by providing heat to help the fuel to ignite. SEE FIGURE 19–14.
As the temperature of the glow plug increases, the resistance of the heating element inside increases, thereby reducing the current in amperes needed by the glow plugs.
OPERATION Most glow plugs used in newer vehicles are controlled by the powertrain control module, which monitors coolant temperature and intake air temperature. The glow plugs are turned on or pulsed on or off depending on the temperature of the engine. The PCM will also keep the glow plug turned on after the engine starts, to reduce white exhaust smoke (unburned fuel) and to improve idle quality after starting. SEE FIGURE 19–15. The “wait to start” lamp (if equipped) will light when the engine and the outside temperatures are low to allow time for the glow plugs to get hot. HEATED INLET AIR Some diesel engines, such as the Dodge Cummins and the General Motors 6.6 liter Duramax V-8, use an electrical heater wire to warm the intake air to help in cold weather starting and running. SEE FIGURE 19–16.
FIGURE 19–14 A glow plug assortment showing the various types and sizes of glow plugs used. Always use the specified glow plugs.
GLOW PLUG RELAY CONTROL
ENGINE CONTROL MODULE (ECM)
HOT AT ALL TIMES
BATTERY FUSE 175 A
3
HOT IN RUN AND START
FUSE HOLDER
POWER DISTRIBUTION
FUEL HEATER FUSE 15 A
FUSIBLE LINK
FUSE BLOCK– UNDERHOOD
FUSIBLE LINK
3
GLOW PLUG RELAY
GLOW PLUG/INTAKE HEATER RELAY ASSEMBLY
INTAKE AIR (IA) HEATER RELAY FUSIBLE LINK
FUSIBLE LINK
INTAKE AIR (IA) HEATER
GLOW PLUG 2
GLOW PLUG 4
GLOW PLUG 6
GLOW PLUG 8
GLOW PLUG 1
GLOW PLUG 3
GLOW PLUG 5
GLOW PLUG 7
G101
52
C1
GLOW PLUG SIGNAL
78
29
IA HEATER RELAY CONTROL
C1
INTAKE HEATER DIAG 1
62
C2
INTAKE HEATER DIAG 2
ENGINE CONTROL MODULE
FIGURE 19–15 A schematic of a typical glow plug circuit. Notice that the glow plug relay and intake air heater relay are both computer controlled.
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APP SENSOR 5V AP
P#
4V
2
3V
APP #
3
2V 1V
AP
P#
1
0 25%
50%
75%
100%
PERCENTAGE THROTTLE OPENING
FIGURE 19–16 A wire-wound electric heater is used to warm the intake air on some diesel engines.
?
FREQUENTLY ASKED QUESTION
How Can You Tell If Gasoline Has Been Added to the Diesel Fuel by Mistake? If gasoline has been accidentally added to diesel fuel and is burned in a diesel engine, the result can be very damaging to the engine. The gasoline can ignite faster than diesel fuel, which would tend to increase the temperature of combustion. This high temperature can harm injectors and glow plugs, as well as pistons, head gaskets, and other major diesel engine components. If contaminated fuel is suspected, first smell the fuel at the filler neck. If the fuel smells like gasoline, then the tank should be drained and refilled with diesel fuel. If the smell test does not indicate a gasoline or any rancid smell, then test a sample for proper specific gravity. NOTE: Diesel fuel designed for on-road use should be green. Red diesel fuel (high sulfur) should only be found in off-road or farm equipment.
ENGINE-DRIVEN VACUUM PUMP Because a diesel engine is unthrottled, it creates very little vacuum in the intake manifold. Several engine and vehicle components operate using vacuum, such as the exhaust gas recirculation (EGR) valve and the heating and ventilation blend and air doors. Most diesels used in cars and light trucks are equipped with an engine-driven vacuum pump to supply the vacuum for these components.
DIESEL FUEL HEATERS Diesel fuel heaters help prevent power loss and stalling in cold weather. The heater is placed in the fuel line between the tank and the primary filter. Some coolant heaters are thermostatically controlled, which allows fuel to bypass the heater once it has reached operating temperature.
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FIGURE 19–17 A typical accelerator pedal position (APP) sensor uses three different sensors in one package with each creating a different voltage as the accelerator is moved.
ACCELERATOR PEDAL POSITION SENSOR Some light-truck diesel engines are equipped with an electronic throttle to control the amount of fuel injected into the engine. Because a diesel engine does not use a throttle in the air intake, the only way to control engine speed is by controlling the amount of fuel being injected into the cylinders. Instead of a mechanical link from the accelerator pedal to the diesel injection pump, a throttle-by-wire system uses an accelerator pedal position (APP) sensor. To ensure safety, it consists of three separate sensors that change in voltage as the accelerator pedal is depressed. SEE FIGURE 19–17. The computer checks for errors by comparing the voltage output of each of the three sensors inside the APP and compares them to what they should be if there are no faults. If an error is detected, the engine and vehicle speed are often reduced.
DIESEL ENGINE TURBOCHARGERS TURBOCHARGED DIESELS A turbocharger greatly increases engine power by pumping additional compressed air into the combustion chambers. This allows a greater quantity of fuel to be burned in the cylinders resulting in greater power output. In a turbocharger, the turbine wheel spins as exhaust gas flows out of the engine and drives the turbine blades. The turbine spins the compressor wheel at the opposite end of the turbine shaft, pumping air into the intake system. SEE FIGURE 19–18. AIR CHARGE COOLER The first component in a typical turbocharger system is an air filter through which ambient air passes before entering the compressor. The air is compressed, which raises its density (mass/unit volume). All currently produced light-duty diesels use an air charge cooler whose purpose is to cool the compressed air to further raise the air density. Cooler air entering the engine means more power can be produced by the engine. SEE FIGURE 19–19.
VARIABLE TURBOCHARGER
A variable turbocharger is used on many diesel engines for boost control. Boost pressure is controlled independent of engine speed and a wastegate is not needed. The adjustable vanes mount to a unison ring that allows the vanes to move. As the position of the unison ring rotates, the vanes change angle. The vanes are opened to minimize flow at the turbine and exhaust back pressure at low engine speeds. To increase turbine speed, the vanes are closed. The velocity of the exhaust gases increases, as does the speed of the turbine. The unison ring is connected to a cam that is positioned by a rack-and-pinion gear. The turbocharger’s vane position actuator solenoid connects to a hydraulic piston, which moves the rack to rotate the pinion gear and cam. SEE FIGURE 19–20. The turbocharger vane position control solenoid valve is used to advance the unison ring’s relationship to the turbine and thereby articulate the vanes. This solenoid actuates a spool valve that applies oil pressure to either side of a piston. Oil flow has three modes: apply, hold, and release.
The turbocharger vane position actuation is controlled by the ECM, which can change turbine boost efficiency independent of engine speed. The ECM provides a control signal to the valve solenoid along with a low-side reference. A pulse-width-modulated signal from the ECM moves the valve to the desired position.
EXHAUST GAS RECIRCULATION The EGR system recycles some exhaust gas back into the intake stream to cool combustion, which reduces oxides of nitrogen (NOx) emissions. The EGR system includes:
Plumbing that carries some exhaust gas from the turbocharger exhaust inlet to the intake ports
Apply moves the vanes toward a closed position.
EGR control valve
Hold maintains the vanes in a fixed position.
Release moves the vanes toward the open position.
Stainless steel cooling element used to cool the exhaust gases ( SEE FIGURE 19–21.) RACK
HYDRAULIC PISTON
CAM
UNISON RING
TURBINE
FIGURE 19–18 A Cummins diesel turbocharger is used to increase the power and torque of the engine.
ADJUSTABLE VANES
FIGURE 19–20 A variable vane turbocharger allows the boost to be controlled without the need of a wastegate. CHARGE AIR COOLER
AMBIENT AIR INTAKE EXHAUST STROKE
COMPRESSOR
TURBINE
EXHAUST
FIGURE 19–19 An air charge cooler is used to cool the compressed air.
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FINE BEACH SAND (90μm IN. DIAMETER)
HUMAN HAIR ( -70 μm IN. DIAMETER)
FIGURE 19–21 A cutaway showing the exhaust cooler. The cooler the exhaust is, the more effective it is in controlling NOx emissions.
PM10 (< 10 μm IN. DIAMETER)
PM2.5 (< 2.5 μm IN. DIAMETER)
FIGURE 19–22 Relative size of particulate matter to a human hair.
?
The EGR valve is PCM controlled and often uses a DC stepper motor and worm gear to move the valve stem open. The gear is not attached to the valve and can only force it open. Return spring force closes the valve. The EGR valve and sensor assembly is a five-wire design. The PCM uses the position sensor to verify that valve action is as commanded.
What Is the Big Deal for the Need to Control Very Small Soot Particles? For many years soot or particulate matter (PM) was thought to be less of a health concern than exhaust emissions from gasoline engines. It was felt that the soot could simply fall to the ground without causing any noticeable harm to people or the environment. However, it was discovered that the small soot particulates when breathed in are not expelled from the lungs like larger particles but instead get trapped in the deep areas of the lungs where they accumulate.
DIESEL PARTICULATE MATTER PARTICULATE MATTER STANDARDS Particulate matter (PM), also called soot, refers to tiny particles of solid or semisolid material suspended in the atmosphere. This includes particles between 0.1 micron and 50 microns in diameter. The heavier particles, larger than 50 microns, typically tend to settle out quickly due to gravity. Particulates are generally categorized as follows:
Total suspended particulate (TSP). Refers to all particles between 0.1 and 50 microns. Up until 1987, the Environmental Protection Agency (EPA) standard for particulates was based on levels of TSP.
PM10. Refers to particulate matter of 10 microns or less (approximately 1/6 the diameter of a human hair). EPA has a standard for particles based on levels of PM10.
PM2.5. Refers to particulate matter of 2.5 microns or less (approximately 1/20 the diameter of a human hair), also called “fine” particles. In July 1997, the EPA approved a standard for PM2.5. SEE FIGURE 19–22.
SOOT CATEGORIES
In general, soot particles produced by diesel combustion fall into the following categories.
DIESEL OXIDATION CATALYST PURPOSE AND FUNCTION Diesel oxidation catalysts (DOC) are used in all light-duty diesel engines, since 2007. They consist of a flow-through honeycomb-style substrate structure that is wash coated with a layer of catalyst materials, similar to those used in a gasoline engine catalytic converter. These materials include the precious metals platinum and palladium, as well as other base metal catalysts. Catalysts chemically react with exhaust gas to convert harmful nitrogen oxide into nitrogen dioxide, and to oxidize absorbed hydrocarbons. The chemical reaction acts as a combustor for the unburned fuel that is characteristic of diesel compression ignition. The main function of the DOC is to start a regeneration event by converting the fuel-rich exhaust gases to heat. The DOC also reduces:
Carbon monoxide (CO) Hydrocarbons (HC)
Fine. Less than 2.5 microns
Ultrafine. Less than 0.1 micron, and make up 80% to 95% of soot
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FREQUENTLY ASKED QUESTION
Odor-causing compounds such as aldehydes and sulfur
SEE FIGURE 19–23.
PM H2O
NO2 CO2
SOOT BUILDUP HC PM
CO
FIGURE 19–23 Chemical reaction within the DOC.
FIGURE 19–25 The soot is trapped in the passages of the DPF. The exhaust has to flow through the sides of the trap and exit.
EGT SENSOR 1
DOC
EGT SENSOR 2
DPF
FIGURE 19–24 Aftertreatment of diesel exhaust is handled by the DOC and DPF.
DIESEL EXHAUST PARTICULATE FILTER PURPOSE AND FUNCTION Diesel exhaust particulate filters (DPFs) are used in all light-duty diesel vehicles, since 2007, to meet the exhaust emissions standards. The heated exhaust gas from the DOC flows into the DPF, which captures diesel exhaust gas particulates (soot) to prevent them from being released into the atmosphere. This is done by forcing the exhaust through a porous cell which has a silicon carbide substrate with honeycomb-cell-type channels that trap the soot. The main difference between the DPF and a typical catalyst filter is that the entrance to every other cell channel in the DPF substrate is blocked at one end. So instead of flowing directly through the channels, the exhaust gas is forced through the porous walls of the blocked channels and exits through the adjacent open-ended channels. This type of filter is also referred to as a “wall-flow” filter. SEE FIGURE 19–24. OPERATION
Soot particulates in the gas remain trapped on the DPF channel walls where, over time, the trapped particulate matter will begin to clog the filter. The filter must therefore be purged periodically to remove accumulated soot particles. The process of purging soot from the DPF is described as regeneration. When the temperature of the exhaust gas is increased, the heat incinerates the soot particles trapped in the filter and is effectively renewed. SEE FIGURE 19–25.
FIGURE 19–26 EGT 1 and EGT 2 are used by the PCM to help control after treatment.
EGT sensor 1 is positioned between the DOC and the DPF where it can measure the temperature of the exhaust gas entering the DPF.
EGT sensor 2 measures the temperature of the exhaust gas stream immediately after it exits the DPF.
The powertrain control module monitors the signals from the EGT sensors as part of its calibrations to control DPF regeneration. Proper exhaust gas temperatures at the inlet of the DPF are crucial for proper operation and for starting the regeneration process. Too high a temperature at the DPF will cause the DPF substrate to melt or crack. Regeneration will be terminated at temperatures above 1,470°F (800°C). With too low a temperature, self-regeneration will not fully complete the soot-burning process. SEE FIGURE 19–26.
DPF DIFFERENTIAL PRESSURE SENSOR The DPF differential pressure sensor (DPS) has two pressure sample lines.
One line is attached before the DPF.
The other is located after the DPF.
The exact location of the DPS varies by vehicle model type such as medium duty, pickup, or van. By measuring the exhaust supply (upstream) pressure from the DOC, and the post DPF (downstream) pressure, the PCM can determine differential pressure, also called “delta” pressure, across the DPF. Data from the DPF differential pressure sensor is used by the PCM to calibrate for controlling DPF exhaust system operation.
DIESEL PARTICULATE FILTER REGENERATION EXHAUST GAS TEMPERATURE SENSORS
The following two exhaust gas temperature sensors are used to help the PCM control the DPF.
The primary reason for soot removal is to prevent the buildup of exhaust back pressure. Excessive back pressure increases fuel consumption, reduces power output, and can potentially cause engine
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MAIN CLEANED AREA
R E G E N E R A T I O N
PILOT
PRE
AFTER
SOOT
CLEANED AREA
FIGURE 19–27 Regeneration burns the soot and renews the DPF. damage. Several factors can trigger the diesel PCM to perform regeneration, including:
Distance since last DPF regeneration
Fuel used since last DPF regeneration
Engine run time since last DPF regeneration
Exhaust differential pressure across the DPF
0.4 ms
POST
FIGURE 19–28 The post injection pulse occurs to create the heat needed for regeneration.
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FREQUENTLY ASKED QUESTION
Will the Postinjection Pulses Reduce Fuel Economy? Maybe. Due to the added fuel-injection pulses and late fuel-injection timing, an increase in fuel consumption may be noticed on the driver information center (DIC) during the regeneration time period. A drop in overall fuel economy should not be noticeable. SEE FIGURE 19–28.
DPF REGENERATION PROCESS
A number of engine components are required to function together for the regeneration process to be performed, as follows: 1. PCM controls that impact DPF regeneration include late post injections, engine speed, and adjusting fuel pressure. 2. Adding late post injection pulses provides the engine with additional fuel to be oxidized in the DOC, which increases exhaust temperatures entering the DPF to 900°F (500°C) or higher. SEE FIGURE 19–27. 3. The intake air valve acts as a restrictor that reduces air entry to the engine, which increases engine operating temperature.
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FREQUENTLY ASKED QUESTION
What Is an Exhaust Air Cooler? An exhaust air cooler is simply a section of tailpipe that has slits for air to enter. As hot exhaust rushes past the gap, outside air is drawn into the area which reduces the exhaust discharge temperature. The cooler significantly lowers exhaust temperature at the tailpipe from about 800°F (430°C) to approximately 500°F (270°C). SEE FIGURE 19–29.
4. The intake air heater may also be activated to warm intake air during regeneration.
TYPES OF DPF REGENERATION
DPF regeneration can be initiated in a number of ways, depending on the vehicle application and operating circumstances. The two main regeneration types are as follows:
Passive regeneration. During normal vehicle operation when driving conditions produce sufficient load and exhaust temperatures, passive DPF regeneration may occur. This passive regeneration occurs without input from the PCM or the driver. A passive regeneration may typically occur while the vehicle is being driven at highway speed or towing a trailer.
Active regeneration. Active regeneration is commanded by the PCM when it determines that the DPF requires it to remove excess soot buildup and conditions for filter regeneration have been met. Active regeneration is usually not noticeable to the driver. The vehicle needs to be driven at speeds above 30 mph for approximately 20 to 30 minutes to
WARNING Tailpipe outlet exhaust temperature will be greater than 572°F (300°C) during service regeneration. To help prevent personal injury or property damage from fire or burns, keep vehicle exhaust away from any object and people.
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complete a full regeneration. During regeneration, the exhaust gases reach temperatures above 1,000°F (550°C). Active regeneration is usually not noticeable to the driver.
ASH LOADING
Regeneration will not burn off ash. Only the particulate matter (PM) is burned off during regeneration. Ash is a noncombustible by-product from normal oil consumption. Ash accumulation in the DPF will eventually cause a restriction in the particulate filter. To service an ash-loaded DPF, the DPF will need to be removed from the vehicle and cleaned or replaced. Low ash content engine oil (API CJ-4) is required for vehicles with the DPF system. The CJ-4 rated oil is limited to 1% ash content.
SELECTIVE CATALYTIC REDUCTION PURPOSE AND FUNCTION
Selective catalytic reduction (SCR) is a method used to reduce NOx emissions by injecting urea into the exhaust stream. Instead of using large amounts of exhaust gas recirculation (EGR), the SCR system uses a urea. Urea is used as a nitrogen fertilizer. It is colorless, odorless, and nontoxic. Urea is called diesel exhaust fluid (DEF) in North America and AdBlue in Europe. SEE FIGURE 19–30.
OUTSIDE AIR
OUTSIDE AIR OXIDATION CATALYST
ENGINE EXHAUST
UREA SCR
NH 3 OXIDE CATALYST
NO X
N2
CO
CO 2
HC
H2 O
PM
FIGURE 19–29 The exhaust is split into two outlets and has slits to help draw outside air in as the exhaust leaves the tailpipe. The end result is cooler exhaust gases exiting the tailpipe.
PM UREA DOUSING SYSTEM
FIGURE 19–31 Urea (diesel exhaust fluid) injection is used to reduce NOx exhaust emissions. It is injected after the diesel oxidation catalyst (DOC) and before the diesel particulate filter (DPF) on this 6.7 liter Ford diesel engine.
Difficult to find local sources of urea
Increased costs to the vehicle owner due to having to refill the urea storage tank
DIESEL EXHAUST SMOKE DIAGNOSIS
FIGURE 19–30 Diesel exhaust fluid costs $3 to $4 a gallon and is housed in a separate container that holds from 5 to 10 gallons, or enough to last until the next scheduled oil change in most diesel vehicles that use SCR. The urea is injected into the catalyst where it sets off a chemical reaction which converts nitrogen oxides (NOx) into nitrogen (N2) and water (H2O). Vehicle manufacturers size the onboard urea storage tank so that it needs to be refilled at about each scheduled oil change or every 7,500 miles (12,000 km). A warning light alerts the driver when the urea level needs to be refilled. If the warning light is ignored and the diesel exhaust fluid is not refilled, current EPA regulations require that the operation of the engine be restricted and may not start unless the fluid is refilled. This regulation is designed to prevent the engine from being operated without the fluid, which, if not, would greatly increase exhaust emissions. SEE FIGURE 19–31.
ADVANTAGES OF SCR Using urea injection instead of large amounts of EGR results in the following advantages.
Potential higher engine power output for the same size engine
Reduced NOx emissions up to 90%
Reduced HC and CO emissions up to 50%
Reduced particulate matter (PM) by 50%
DISADVANTAGES OF SCR
Using urea injection instead of large amounts of EGR results in the following disadvantages.
Onboard storage tank required for the urea
Although some exhaust smoke is considered normal operation for many diesel engines, especially older units, the cause of excessive exhaust smoke should be diagnosed and repaired.
BLACK SMOKE
Black exhaust smoke is caused by incomplete combustion because of a lack of air or a fault in the injection system that could cause an excessive amount of fuel in the cylinders. Items that should be checked include the following:
Fuel specific gravity (API gravity)
Injector balance test to locate faulty injectors using a scan tool
Proper operation of the engine coolant temperature (ECT) sensor
Proper operation of the fuel rail pressure (FRP) sensor
Restrictions in the intake or turbocharger
Engine oil usage
WHITE SMOKE
White exhaust smoke occurs most often during cold engine starts because the smoke is usually condensed fuel droplets. White exhaust smoke is also an indication of cylinder misfire on a warm engine. The most common causes of white exhaust smoke include:
Inoperative glow plugs
Low engine compression
Incorrect injector spray pattern
Coolant leak into the combustion chamber
GRAY OR BLUE SMOKE Blue exhaust smoke is usually due to oil consumption caused by worn piston rings, scored cylinder walls, or defective valve stem seals. Gray or blue smoke can also be caused by a defective injector(s). D I E SE L E N G I N E O PE RAT I O N A N D D IA GN OS IS
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DIESEL PERFORMANCE DIAGNOSIS Diesel engines can be diagnosed using a scan tool in most cases, because most of the pressure sensors values can be displayed. Common faults include:
Hard starting
No start
Extended cranking before starting
Low power
Using a scan tool, check the sensor values in CHART 19–2 to help pin down the source of the problem. Also check the minimum pressures that are required to start the engine if a no-start condition is being diagnosed. SEE FIGURE 19–32.
DIESEL TROUBLESHOOTING CHART 5.9 Dodge Cummins 2003–2008 Low-pressure pump
8–12 PSI
Pump amperes
4A
Pump volume
45 oz. in 30 sec.
High-pressure pump
5,000–23,000 PSI
Idle PSI
5,600–5,700 PSI
Electronic Fuel Control (EFC) maximum fuel pressure
Disconnect EFC to achieve maximum pressure
Injector volts
90 V
Injector amperes
20 A
Glow plug amperes
60–80 A ⴛ 2 (120–160 A)
Minimum PSI to start
5,000 PSI GM Duramax 2001–2008
Low-pressure pump vacuum
2–10 in. Hg
Pump amperes
NA
Pump volume
NA
High-pressure pump
5 K-2.3 K-2.6 K PSI
Idle PSI
5,000–6,000 PSI (30–40 MPa)
Fuel Rail Pressure Regulator (FRPR) maximum fuel pressure
Disconnect to achieve maximum pressure
Injector volts
48 V or 93 V
Injector amperes
20 A
Glow plug amperes
160 A
Minimum to start
1,500 PSI (10 MPa) Sprinter 2.7 2002–2006
Low-pressure pump
6–51 PSI
High-pressure pump
800–23,000 PSI
Idle PSI
4,900 PSI
Fuel Rail Pressure Control (FRPC) maximum fuel pressure
Apply power and ground to FRPC to achieve maximum pressure
Injector volts
80 V
Injector amperes
20 A
Glow plug amperes
17 A each (85–95 A total)
Minimum to start
3,200 PSI (1–1.2 V to start) 6.0 Powerstroke 2003–2008
Low-pressure pump
50–60 PSI
High-pressure pump
500–4,000 PSI
Idle PSI
500 PSI ⴙ
Injection Pressure Regulator (IPR) maximum fuel pressure
Apply power and ground to IPR
Injector volts
48 V
Injector amperes
20 A
Glow plug amperes
20–25 A each (160–200 A total)
Minimum to start
500 PSI (0.85 V)
CHART 19–2 The values can be obtained by using a scan tool and basic test equipment. Always follow the vehicle manufacturer’s recommended procedures.
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FIGURE 19–32 A pressure gauge checking the fuel pressure from the lift pump on a Cummins 6.7 liter diesel.
COMPRESSION TESTING
FIGURE 19–33 A compression gauge that is designed for the higher compression rate of a diesel engine should be used when checking the compression.
A compression test is fundamental for determining the mechanical condition of a diesel engine. Worn piston rings can cause low power and excessive exhaust smoke. To test the compression on a diesel engine, the following will have to be done.
Remove the glow plug (if equipped) or the injector.
Use a diesel compression gauge, as the compression is too high to use a gasoline engine compression gauge.
A diesel engine should produce at least 300 PSI (2,068 kPa) of compression pressure and all cylinders should be within 50 PSI (345 kPa) of each other. SEE FIGURE 19–33.
GLOW PLUG RESISTANCE BALANCE TEST Glow plugs increase in resistance as their temperature increases. All glow plugs should have about the same resistance when checked with an ohmmeter. A similar test of the resistance of the glow plugs can be used to detect a weak cylinder. This test is particularly helpful on a diesel engine that is not computer controlled. To test for even cylinder balance using glow plug resistance, perform the following on a warm engine. 1. Unplug, measure, and record the resistance of all glow plugs. 2. With the wires still removed from the glow plugs, start the engine. 3. Allow the engine to run for several minutes to allow the combustion inside the cylinder to warm the glow plugs.
FIGURE 19–34 A typical pop tester used to check the spray pattern of a diesel engine injector.
INJECTOR POP TESTING
4. Measure the plugs and record the resistance of all glow plugs. 5. The resistance of all glow plugs should be higher than at the beginning of the test. A glow plug that is in a cylinder that is not firing correctly will not increase in resistance as much as the others. 6. Another test is to measure exhaust manifold temperature at each exhaust port using an infrared thermometer or a pyrometer. Misfiring cylinders will run cold.
A pop tester is a device used for checking a diesel injector nozzle for proper spray pattern. The handle is depressed and pop-off pressure is displayed on the gauge. SEE FIGURE 19–34. The spray pattern should be a hollow cone, but will vary depending on design. The nozzle should also be tested for leakage (dripping of the nozzle) while under pressure. If the spray pattern is not correct, then cleaning, repairing, or replacing the injector nozzle may be necessary.
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20% opacity
40% opacity
60% opacity
80% opacity
100% opacity
CHART 19–3 An opacity test is sometimes used during a state emission test on diesel engines. TECH TIP Always Use Cardboard to Check for High-Pressure Leaks If diesel fuel is found on the engine, a high-pressure leak could be present. When checking for such a leak, wear protective clothing including safety glasses, a face shield, gloves, and a long-sleeved shirt. Then use a piece of cardboard to locate the high-pressure leak. When a Duramax diesel is running, the pressure in the common rail and injector tubes can reach over 20,000 PSI. At these pressures, the diesel fuel is atomized and cannot be seen but can penetrate the skin and cause personal injury. A leak will be shown as a dark area on the cardboard. When a leak is found, shut off the engine and find the exact location of the leak without the engine running. CAUTION: Sometimes a leak can actually cut through the cardboard, so use extreme care.
DIESEL EMISSION TESTING OPACITY TEST
The most common diesel exhaust emission test used in state or local testing programs is called the opacity test. Opacity means the percentage of light that is blocked by the exhaust smoke.
A 0% opacity means that the exhaust has no visible smoke and does not block light from a beam projected through the exhaust smoke.
A 100% opacity means that the exhaust is so dark that it completely blocks light from a beam projected through the exhaust smoke.
A 50% opacity means that the exhaust blocks half of the light from a beam projected through the exhaust smoke. SEE CHART 19–3.
FIGURE 19–35 The letters on the side of this injector on a Cummins 6.7 liter diesel indicate the calibration number for the injector.
TECH TIP Do Not Switch Injectors In the past, it was common practice to switch diesel fuel injectors from one cylinder to another when diagnosing a dead cylinder problem. However, most high-pressure common rail systems used in new diesels utilize precisely calibrated injectors that should not be mixed up during service. Each injector has its own calibration number.
SEE FIGURE 19–35.
SNAP ACCELERATION TEST In a snap acceleration test, the vehicle is held stationary, with wheel chocks in place and brakes released as the engine is rapidly accelerated to high idle, with the transmission in neutral while smoke emissions are measured. This test is conducted a minimum of six times and the three most consistent measurements are averaged for a final score. ROLLING ACCELERATION TEST
Vehicles with a manual transmission are rapidly accelerated in low gear from an idle speed to a maximum governed RPM while the smoke emissions are measured.
STALL ACCELERATION TEST Vehicles with automatic transmissions are held in a stationary position with the parking brake and service brakes applied while the transmission is placed in “drive.” The accelerator is depressed and held momentarily while smoke emissions are measured. The standards for diesels vary according to the type of vehicle and other factors, but usually include a 40% opacity or less.
REVIEW QUESTIONS 1. What is the difference between direct injection and indirect injection? 2. What are the three phases of diesel ignition? 3. What are the two most commonly used types of diesel injection systems?
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4. Why are glow plugs kept working after the engine starts? 5. What exhaust aftertreatment is needed to achieve exhaust emission standards for vehicles 2007 and newer? 6. What are the advantages and disadvantages of SCR?
CHAPTER QUIZ 1. How is diesel fuel ignited in a warm diesel engine? a. Glow plugs b. Heat of compression c. Spark plugs d. Distributorless ignition system 2. Which type of diesel injection produces less noise? a. Indirect injection (IDI) c. Common rail b. Direct injection d. Distributor injection 3. Which diesel injection system requires the use of a glow plug? a. Indirect injection (IDI) b. High-pressure common rail c. Direct injection d. Distributor injection 4. The three phases of diesel ignition include ______________. a. Glow plug ignition, fast burn, slow burn b. Slow burn, fast burn, slow burn c. Ignition delay, rapid combustion, controlled combustion d. Glow plug ignition, ignition delay, controlled combustion 5. What fuel system component is used in a vehicle equipped with a diesel engine that is seldom used on the same vehicle when it is equipped with a gasoline engine? a. Fuel filter c. Fuel return line b. Fuel supply line d. Water-fuel separator
chapter
6. The diesel injection pump is usually driven by a ______________. a. Gear off the camshaft c. Shaft drive off the crankshaft b. Belt off the crankshaft d. Chain drive off the camshaft 7. Which diesel system supplies high-pressure diesel fuel to all of the injectors all of the time? a. Distributor c. High-pressure common rail b. Inline d. Rotary 8. Glow plugs should have high resistance when ______________ and lower resistance when ______________. a. Cold/warm c. Wet/dry b. Warm/cold d. Dry/wet 9. Technician A says that glow plugs are used to help start a diesel engine and are shut off as soon as the engine starts. Technician B says that the glow plugs are turned off as soon as a flame is detected in the combustion chamber. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 10. What part should be removed to test cylinder compression on a diesel engine? a. Injector b. Intake valve rocker arm and stud c. Glow plug d. Glow plug or injector
COOLANT
20 OBJECTIVES: After studying Chapter 20, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “D” (Lubrication and Cooling Systems Diagnosis and Repair). • Describe the various types of antifreeze coolants. • Discuss how to store, recycle, and discard used coolant. • Discuss how to test coolant. KEY TERMS: DEX-COOL 176 • Electrolysis 180 • Embittered coolant 177 • Ethylene glycol based coolant 176 • Galvanic activity 180 • Hybrid organic acid technology (HOAT) 177 • Inorganic acid technology (IAT) 176 • Organic acid technology (OAT) 176 • Passivation 181 • Phosphate hybrid organic acid technology (PHOAT) 177 • Propylene glycol (PG) 177 • Refractometer 179
COOLANT FUNDAMENTALS PURPOSE OF COOLANT
Coolant is used in the cooling system
because it: 1. Transfers heat from the engine to the radiator 2. Protects the engine and the cooling system from rust and corrosion 3. Prevents freezing in cold climates Coolant is a mixture of antifreeze and water. Water is able to absorb more heat per gallon than any other liquid coolant. Under standard conditions, the following occurs.
Water boils at 212°F (100°C) at sea level.
Water freezes at 32°F (0°C).
When water freezes, it increases in volume by about 9%. The expansion of the freezing water can easily crack engine blocks, cylinder heads, and radiators.
A curve depicting freezing point as compared with the percentage of antifreeze mixture is shown in FIGURE 20–1.
FREEZING/BOILING TEMPERATURES
It should be noted that the freezing point increases as the antifreeze concentration is
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40 30 20 TEMPERATURE °F
10 0 -10 -20 -30 -40 -50 -60 -70 -80
0 10 20 30 40 50 60 70 80 90 100 PERCENT ANTIFREEZE IN COOLANT
FIGURE 20–1 Graph showing the relationship of the freezing point of the coolant to the percentage of antifreeze used in the coolant. 340 330 320 310 300 TEMPERATURE °F
290 280 270 260 250 240
FIGURE 20–3 Havoline was the first company to make and market OAT coolant. General Motors uses the term DEX-COOL. Regardless of the type of coolant and its color, the only difference among all original equipment coolants is in the additives. This means that about 97% of all coolants are the same. The only difference is in the additive package and color used to help identify the coolant.
230 220 210 200 0 10 20 30 40 50 60 70 80 90 100 PERCENT ANTIFREEZE IN COOLANT
FIGURE 20–2 Graph showing how the boiling point of the coolant increases as the percentage of antifreeze in the coolant increases. increased above 60%. The normal mixture is 50% antifreeze and 50% water. Ethylene glycol antifreeze contains:
Anticorrosion additives
Rust inhibitors
Water pump lubricants
At the maximum level of protection, an ethylene glycol concentration of 60% will absorb about 85% as much heat as will water. Ethylene glycol based antifreeze also has a higher boiling point than water. A curve depicting freezing point as compared with the percentage of antifreeze mixture is shown in FIGURE 20–2. If the coolant boils, it vaporizes and does not act as a cooling agent because it is not in liquid form or in contact with the cooling surfaces. All coolants have rust and corrosion inhibitors to help protect the metals in the engine and cooling systems.
COOLANT COMPOSITION All manufacturers recommend the use of ethylene glycol based coolant, which contains:
TYPES OF COOLANT INORGANIC ACID TECHNOLOGY
Inorganic additive technology (IAT) is conventional coolant that has been used for over 50 years. Most conventional green antifreeze contains inorganic salts such as:
Sodium silicate (silicates)
Phosphates
Borates
Silicates have been found to be the cause of erosive wear to water pump impellers. The color of IAT coolant is green. Phosphates in these coolants can cause deposits to form if used with water that is hard (contains minerals). IAT coolants used in new vehicles were phased out in the mid-1990s.
ORGANIC ACID TECHNOLOGY
Organic acid technology (OAT) coolant contains ethylene glycol, but does not contain silicates or phosphates. The color of this type of coolant is usually orange. DEX-COOL, developed by Havoline, is just one brand of OAT coolant, which has been used in General Motors vehicles since 1996. SEE FIGURE 20–3. DEX-COOL uses ethylhexanoic acid (2-EH) as a corrosive inhibitor. 2-EH is prone to damage plastics, such as Nylon 6.6 used in intake manifold gaskets and radiators. Other brands of OAT coolant that are also orange but do not contain 2-EH include:
Ethylene glycol (EG): 47%
Water: 50%
Zerex G30 or G05 OAT
Additives: 3%
Peak Global OAT
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FREQUENTLY ASKED QUESTION
What Is a “G” Coolant? The “G” coolants come from the trade name Glysantin of BASF in Europe and Valvoline (Zerex) in the United States. The following is a summary of the types listed by G number. • G05: different from DEX-COOL in certain amounts of additives • G30 and G34: nonsilicate and phosphate free • G11: blue VW used before 1997 • G12: pink/red VW 1997⫹ (purple VW 2003⫹) • HOAT formulation • Phosphate free • G48: low silicate and phosphate free • Blue • Nitrates, amines, phosphate (NAP) free
These coolants are usually available in premix (with water) and pure coolant containers.
HYBRID ORGANIC ACID TECHNOLOGY
A newer variation of this technology is called hybrid organic acid technology (HOAT). It is similar to the OAT-type antifreeze as it uses organic acid salts (carboxylates) that are not abrasive to water pumps, yet provide the correct pH. The pH of the coolant is usually above 11. A pH of 7 is neutral, with lower numbers indicating an acidic solution and higher numbers indicating an alkaline solution. If the pH is too high, the coolant can cause scaling and reduce the heat transferability of the coolant. If the pH is too low, the resulting acidic solution could cause corrosion of the engine components exposed to the coolant. HOAT coolants can be green, orange, yellow, gold, pink, red, or blue. Samples of HOAT coolants include:
VW/Audi pink. Contains some silicates and an organic acid, and is phosphate free
Mercedes/Ford yellow. Contains low amounts of silicate and no phosphate
Ford yellow. Contains low silicate, no phosphate, and is dyed yellow for identification
Honda blue. Contains a special coolant with just one organic acid
European/Korean blue. Contains low silicates and no phosphates
Asian red. Contains no silicates but has some phosphate
PHOSPHATE HYBRID ORGANIC ACID TECHNOLOGY Phosphate hybrid organic acid technology (PHOAT) is used in Mazda-based Fords (2008⫹), same as Mazda FL-22, and is ethylene glycol based. This coolant is available in a 55% coolant/45% water premix. SEE FIGURE 20–4.
Concentration: 55%
Boiling point (with 15 PSI pressure cap): 270°F (132°C)
Freezing point: ⫺47°F (⫺44°C)
Color: Dark green
Embittered (made to taste bitter so animals will not drink it)
The use of PHOAT coolant in these engines is required to be assured of proper protection of the material used in the engine. It
FIGURE 20–4 Coolant used in Fords that use Mazda engines and in Mazda vehicles. It requires the use of a PHOAT coolant which is dark green.
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FREQUENTLY ASKED QUESTION
What Is “Pet Friendly” Antifreeze? Conventional ethylene glycol antifreeze used by all vehicle manufacturers is attractive to pets and animals because it has a sweet taste. Ethylene glycol is fatal to any animal if swallowed, so any spill should be cleaned up quickly. There are two types of coolant that are safer for use around pets than the conventional type. • Propylene glycol (PG). This type of antifreeze is less attractive to pets and animals because it is not as sweet, but it is still harmful if swallowed. This type of coolant, including the Sierra brand, should not be mixed with any other ethylene glycol based coolant. CAUTION: Some vehicle manufacturers do not recommend the use of propylene glycol coolant. Check the recommendation in the owner manual or service information before using it in a vehicle. • Embittered coolant. This coolant has a small amount of a substance that makes it taste bitter and therefore not appealing to animals. The embittering agent used in ethylene glycol (EG) antifreeze is usually denatonium benzoate, added at the rate of 30 ppm. Oregon and California require all coolant sold in these states since 2004 to be embittered. SEE FIGURE 20–5.
is also only available in premix containers to ensure that the water used meets specifications.
UNIVERSAL COOLANT
Universal coolant is usually a hybrid organic acid technology (HOAT), with extended life, and a lowsilicate, phosphate-free antifreeze/coolant. It can be used in many vehicles, but cannot meet the needs for engines requiring a silicatefree formulation.
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?
FREQUENTLY ASKED QUESTION
What Makes Some Water Bad for Coolant? City water is treated with chloride, which, if the levels are high enough, can cause corrosion problems when used in coolants. Well water may contain iron or other minerals that can affect the coolant and may increase the corrosion or cause electrolysis. Due to the fact that the water quality is often unknown and could affect the engine, many vehicle manufacturers are specifying the use of premixed coolant. In pre-mix coolant, the water is usually demineralized and meets the standards for use in coolant.
?
FIGURE 20–5 Not all embittered coolant is labeled embittered.
FREQUENTLY ASKED QUESTION
Why Is Most Coolant 50/50 with Water? REAL WORLD FIX
According to the freezing point, it appears that the lowest freezing point of coolant is achieved when 70% antifreeze is used with 30% water. While the freezing temperature is lower, the high concentrate of antifreeze reduces the heat transferability of the coolant. Therefore, most vehicle manufacturers specify a 50/50 mixture of antifreeze and water to achieve the best balance between freeze protection and heat conductivity.
If 50% Is Good, 100% Must Be Better A vehicle owner said that the cooling system of his vehicle would never freeze or rust. He said that he used 100% antifreeze (ethylene glycol) instead of a 50/50 mixture with water. However, after the temperature dropped to ⫺20°F (⫺29°C), the radiator froze and cracked. (Pure antifreeze freezes at about 0°F [⫺18°C]). After thawing, the radiator had to be repaired. The owner was lucky that the engine block did not also crack. For best freeze protection with good heat transfer, use a 50/50 mixture of antifreeze and water. A 50/50 mixture of antifreeze and water is the best compromise between temperature protection and the heat transfer that is necessary for cooling system operation. Do not exceed 70% antifreeze (30% water). As the percentage of antifreeze increases, the boiling temperature increases, and freezing protection increases (up to 70% antifreeze), but the heat transfer performance of the mixture decreases.
WATER INTRODUCTION
Water is half of the coolant and can have an effect on the corrosion protection of coolant due to variations in its quality, which is often unknown. As a result, many vehicle manufacturers, such as Honda and Toyota, are specifying the use of premix coolants only. The main reason is that not only can the water/coolant ratio be maintained, but also the quality of the water can be controlled.
PROPERTIES Water is about half of the coolant and is used because of the following qualities. 1. It is inexpensive.
COOLANT FREEZING/ BOILING TEMPERATURES FREEZING POINT An antifreeze and water mixture is an example wherein the freezing point differs from the freezing point of either pure antifreeze or pure water.
Freezing Point
Pure water
32°F (0°C)
Pure antifreeze*
0°F (⫺18°C)
50/50 mixture
⫺34°F (⫺37°C)
70% antifreeze/30% water
⫺84°F (⫺64°C)
*Pure antifreeze is usually 95% ethylene glycol, 2% to 3% water, and 2% to 3% additives.
Depending on the exact percentage of water used, antifreeze (not premixed), as sold in containers, freezes at about 0°F (⫺18°C). Premixed coolant will freeze at about ⫺34°F (⫺37°C).
BOILING POINT The boiling point of antifreeze and water is also a factor of mixture concentrations.
2. It is an efficient heat exchange fluid because of its excellent thermal conductivity (the ability of a material to conduct heat).
Boiling Point at Sea Level
Boiling Point with 15 PSI Pressure Cap
Pure water
212°F (100°C)
257°F (125°C)
4. The boiling point is 212°F (100°C) (at sea level).
50/50 mixture
218°F (103°C)
265°F (130°C)
5. The freezing point is 32°F (0°C).
70/30 mixture
225°F (107°C)
276°F (136°C)
3. It has good specific heat capacity, meaning it takes more heat energy to increase the temperature, versus one with low specific heat capacity.
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If the engine is overheating and the hydrometer reading is near ⫺50°F (⫺60°C), suspect that pure 100% antifreeze is present. For best results, the coolant should have a freezing point lower than ⫺20°F (⫺29°C) and a boiling point above 234°F (112°).
COOLANT TESTING Normal coolant tests include:
Visual inspection. Coolant should be clean and bright.
Freeze/boiling point. A high freezing point or low boiling point indicates dilution (too much water).
pH. The wrong pH indicates buffer loss, which is used to help maintain the pH level.
Coolant voltage. A high voltage indicates the wrong pH or a stray current flow. Various methods are used to test coolant.
HYDROMETER TESTING
Coolant can be checked using a coolant hydrometer. The hydrometer measures the density of the coolant. The higher the density is, the more concentration of antifreeze in the water. Most coolant hydrometers read the freezing and boiling points of the coolant. SEE FIGURE 20–6.
REFRACTOMETER
A refractometer is a tester used to test the freezing point of coolant by placing a few drops of coolant on the prism surface. The technician then holds the unit up to light and looks through the eyepiece for the location of the shadow on the display. A refractometer measures the extent to which light is bent (refracted) to determine the index of refraction of a liquid sample. The refractive index is commonly used for the following:
To identify or confirm the identity of a sample coolant
To determine the purity of a coolant by comparing its refractive index to the value for the pure substance
To determine the concentration of a solute in a solution by comparing the solution’s refractive index to a standard curve
SEE FIGURE 20–7.
TECH TIP Ignore the Wind Chill Factor
FIGURE 20–6 Checking the freezing temperature of the coolant using a hydrometer.
-84
The wind chill factor is a temperature that combines the actual temperature and the wind speed to determine the overall heat loss effect on open skin. Because it is the heat loss factor for open skin, the wind chill temperature is not to be considered when determining antifreeze protection levels. Although moving air makes it feel colder, the actual temperature is not changed by the wind, and the engine coolant will not be affected by the wind chill. If you are not convinced, try placing a thermometer in a room and wait until a stable reading is obtained. Now turn on a fan and have the air blow across the thermometer. The temperature will not change.
1. PLACE A FEW DROPS OF THE SAMPLE FLUID ON THE MEASURING PRISM AND CLOSE THE COVER
-80 -70
1.400
-60
1.350
-50 -40 -34 -30
1.300 1.250 1.200 1.150
1.100
G o o d
-60 -50 -40 -30 -20 -10 -5
-20 F a
i
R e c h a r g e
BATTERY CHARGE
r
-10 -5 0
0 +5 +10
+5 +10
+15
2. HOLD UP TO A LIGHT AND READ THE SCALE
+15 +20 +20 +25
+25
+32
+32 ETHYLENE GLYCOL
˚F
PROPYLENE GLYCOL
FIGURE 20–7 Using a refractometer is an accurate method to check the freezing point of coolant.
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BI-METAL CORROSION
ELECTRONS
ELECTROLYTE
ANODE
FIGURE 20–8 A meter that measures the actual pH of the coolant can be used for all coolants, unlike many test strips that cannot be used to test the pH of red or orange coolants.
PH The term pH comes from a French word, meaning “power of hydrogen,” and is a measure of acidity or alkalinity of a solution.
Less than 7 pH is considered acidic.
Greater than 7 pH is considered alkaline.
CATHODE
(MORE REACTIVE METAL)
(LESS REACTIVE METAL)
FIGURE 20–9 Galvanic activity is created by two dissimilar metals in contact with a liquid, in this case coolant.
The pH of new coolant varies according to the type of coolant used. Typical pH values for new coolant include: IAT: 9 to 10.5 new OAT: 7.5 to 8.5 new (G30 and G34 designations) HOAT: 7.5 to 8.5 new (G05, G48, G11, or G12 designation) PHOAT: 7.5 to 8.5 new When testing for pH, use either a test strip or a pH meter. If using a test strip be sure that it is calibrated to test the type of coolant being used in the vehicle. Used coolant pH readings are usually lower than when the coolant is new and range from between 7.5 and 10 for IAT and lower for used OAT, HOAT, and PHOAT coolants. For best results use a pH tester that measures the actual pH of the coolant. SEE FIGURE 20–8.
GALVANIC ACTIVITY
Galvanic activity is the flow of an electrical current as a result of two different metals in a liquid, which acts like a battery. Galvanic activity does not require an outside source of voltage. The two different metals, usually iron and aluminum, become the plates of the battery and the coolant is the electrolyte. The higher the electrical conductivity of the coolant, the greater is the amount of corrosion. SEE FIGURE 20–9.
ELECTROLYSIS
Electrolysis requires the use of an outside voltage source. The source is usually due to a poor electrical ground connection.
Electrical flow through the cooling system may cause metal to flow into the coolant.
This metal transfer can eat holes in a heater core or radiator.
Electrolysis holes will usually start from the inside and have a dark coloration.
FIGURE 20–10 A test strip can be used to determine the pH and percentage of glycol of the coolant. The percentage of glycol determines the freezing and boiling temperatures, as shown on the bottle that contains the test strips.
STEP 4
Read the meter. If the voltage is above 0.5 V, this indicates excessive galvanic activity. Normal readings should be less than 0.2 V (200 mV). Flush and refill the cooling system.
STEP 5
To test for excessive electrolysis, start the engine and turn on all electrical accessories, including the headlights on high beam.
STEP 6
Read the voltmeter. If the reading is higher than 0.5 V, check for improper body ground wires or connections. Normal readings should be less than 0.3 V (300 mV).
TEST STRIP TESTING
Test strips can be used to check one
or more of the following:
TESTING FOR GALVANIC ACTIVITY AND ELECTROLYSIS A voltmeter set to read DC volts is used to test for galvanic activity and electrolysis. To check for excessive voltage caused by galvanic activity or electrolysis, perform the following steps. STEP 1
Allow the engine to cool and then carefully remove the pressure cap from the radiator.
STEP 2
Set the voltmeter to DC volts and connect the black meter lead to a good engine ground.
STEP 3
Place the red meter lead into the coolant.
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Freeze point
Boiling point
Level of pH
Test strips will change color when they are dipped into the coolant, and the color change is compared to the container. Test strips are fairly accurate, easy to use, and inexpensive. For best results, use test strips that are new and have been stored in a sealed bottle. Using older test strips may affect the accuracy. SEE FIGURE 20–10.
COOLANT REPLACEMENT ISSUES INTERVALS
Coolant should be replaced according to the vehicle manufacturer’s recommended interval.
For most new vehicles using OAT or HOAT type coolant, this interval may be every five years or 150,000 miles (241,000 km), whichever occurs first.
Japanese brand vehicles usually have a replacement interval of three years or 36,000 miles (58,000 km), whichever occurs first.
If the coolant is changed from a long life to a conventional IAT coolant, the replacement interval needs to be changed to every two years or 24,000 miles (39,000 km), whichever occurs first.
PASSIVATION
Passivation is a chemical reaction that takes place between coolant additives and the metal that it protects. This means that a chemical barrier is created between the coolant and
the metals of the engine. When changing coolants, passivation can take from a few days to a few weeks.
Each chemical package does its own passivation.
If you change chemical packages, passivation has to start over.
Therefore, because of passivation concerns, most experts agree that for best results do not change types of coolants. Always use what the vehicle manufacturer recommends. Always check service information for the exact recommended replacement interval for the vehicle being serviced.
RECYCLING COOLANT
Coolant (antifreeze and water) should be recycled. Used coolant may contain heavy metals, such as lead, aluminum, and iron, which are absorbed by the coolant during its use in the engine. Recycle machines filter out these metals and dirt and reinstall the depleted acids. The recycled coolant, restored to be like new, can be reinstalled into the vehicle. CAUTION: Most vehicle manufacturers warn that coolant should not be reused unless it is recycled and the acids restored. However, Mercedes lifetime coolant is very expensive, and according to Mercedes can be drained, filtered, and reused.
REVIEW QUESTIONS 1. What types of coolant are used in vehicles? 2. Why is a 50/50 mixture of antifreeze and water commonly used as a coolant?
4. What are some of the heavy metals that can be present in used coolant? 5. What is the difference between galvanic activity and electrolysis?
3. What are the differences among IAT, OAT, HOAT, and PHOAT coolants?
CHAPTER QUIZ 1. Coolant is water and ______________. a. Methanol c. Kerosene b. Glycerin d. Ethylene glycol 2. As the percentage of antifreeze in the coolant increases, ______________. a. The freeze point decreases (up to a point) b. The boiling point decreases c. The heat transfer increases d. All of the above 3. Adding a chemical to make ethylene glycol coolant bitter to the taste is called ______________. a. Passivation b. Embittered c. Refractometer d. Electrolysis 4. Asian red coolant is what type? a. IAT c. HOAT b. OAT d. PHOAT 5. DEX-COOL is what type of coolant? a. IAT c. HOAT b. OAT d. PHOAT 6. PHOAT coolant is what color? a. Dark green c. Orange b. Red d. Blue
7. DEX-COOL is ______________. a. Propylene glycol b. Ethylene glycol c. Is silicate and phosphate free d. Both b and c 8. Two technicians are discussing testing coolant for proper pH. Technician A says that coolant has a pH above 7 when new and becomes lower with use in an engine. Technician B says that OAT and HOAT coolants have a lower pH when new compared to the old green IAT coolant. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 9. Reusing old coolant is generally not approved by vehicle manufacturers except ______________. a. General Motors c. Chrysler b. Ford d. Mercedes 10. A voltmeter was used to check the coolant and a reading of 0.2 volt with the engine off was measured. A reading of 0.8 volt was measured with the engine running and all electrical accessories turned on. Technician A says that the coolant should be flushed to solve the galvanic activity. Technician B says that the ground wires and connections should be inspected and repaired to solve the electrolysis problem. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
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chapter
21
COOLING SYSTEM OPERATION AND DIAGNOSIS
OBJECTIVES: After studying Chapter 21, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “D” (Lubrication and Cooling Systems Diagnosis and Repair). • Describe how coolant flows through an engine. • Discuss the operation of the thermostat. • Explain the purpose and function of the radiator pressure cap. • Describe the operation and service of water pumps. • Discuss how to diagnose cooling system problems. KEY TERMS: Bar 188 • Bleed holes 191 • Bypass 184 • Centrifugal pump 189 • Coolant recovery system 188 • Cooling fins 186 • Core tubes 186 • Impeller 189 • Parallel flow system 190 • Reverse cooling 189 • Scroll 189 • Series flow system 190 • Series-parallel flow system 191 • Silicone coupling 191 • Steam slits 191 • Surge tank 188 • Thermostatic spring 191
COOLING SYSTEM
SPARK PLUG
PURPOSE AND FUNCTION
Satisfactory cooling system operation depends on the design and operating conditions of the system. The design is based on heat output of the engine, radiator size, type of coolant, size of water pump (coolant pump), type of fan, thermostat, and system pressure. The cooling system must allow the engine to warm up to the required operating temperature as rapidly as possible and then maintain that temperature. Peak combustion temperatures in the engine run from 4,000°F to 6,000°F (2,200°C to 3,300°C). The combustion temperatures will average between 1,200°F and 1,700°F (650°C and 925°C). Continued temperatures as high as this would weaken engine parts, so heat must be removed from the engine. The cooling system keeps the head and cylinder walls at a temperature that is within the range for maximum efficiency. The cooling system removes about one-third of the heat created in the engine. Another third escapes to the exhaust system. SEE FIGURE 21–1.
LOW-TEMPERATURE ENGINE PROBLEMS Engine operating temperatures must be above a minimum temperature for proper engine operation. If the coolant temperature does not reach the specified temperature as determined by the thermostat, then the following engine-related faults can occur.
A P0128 diagnostic trouble code (DTC) can be set. This code indicates “coolant temperature below thermostat regulating temperature,” which is usually caused by a defective thermostat staying open or partially open. Moisture created during the combustion process can condense and flow into the oil. For each gallon of fuel used, moisture equal to a gallon of water is produced. The condensed moisture combines with unburned hydrocarbons and additives to form carbonic acid, sulfuric acid, nitric acid, hydrobromic acid, and hydrochloric acid.
To reduce cold engine problems and to help start engines in cold climates, most manufacturers offer block heaters as an option. These
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EXHAUST 1,500° COOLANT 4,500° COOLANT
PISTON
FIGURE 21–1 Typical combustion and exhaust temperatures.
TECH TIP Overheating Can Be Expensive A faulty cooling system seems to be a major cause of engine failure. Engine rebuilders often have nightmares about seeing their rebuilt engine placed back in service in a vehicle with a clogged radiator. Most engine technicians routinely replace the water pump and all hoses after an engine overhaul or repair. The radiator should also be checked for leaks and proper flow whenever the engine is repaired or replaced. Overheating is one of the most common causes of engine failure.
BYPASS PIPE
WATER JACKET
RADIATOR
COMBUSTION CHAMBER WATER JACKET CORE PLUG
CORE PLUG FAN
THERMOSTAT WATER PUMP
FIGURE 21–3 Coolant flow through a typical engine cooling system.
COOLANT
FIGURE 21–2 Coolant circulates through the water jackets in the engine block and cylinder head.
block heaters are plugged into household current (110 volts AC) and the heating element warms the coolant.
HIGH-TEMPERATURE ENGINE PROBLEMS Maximum temperature limits are required to protect the engine. Higher than normal temperatures can cause the following engine-related issues.
High temperatures will oxidize the engine oil producing hard carbon and varnish. The varnish will cause the hydraulic valve lifter plungers to stick. Higher than normal temperatures will also cause the oil to become thinner (lower viscosity than normal). Thinned oil will also get into the combustion chamber by going past the piston rings and through valve guides to cause excessive oil consumption. The combustion process is very sensitive to temperature. High coolant temperatures raise the combustion temperatures to a point that may cause detonation (also called spark knock or ping) to occur.
COOLING SYSTEM OPERATION PURPOSE AND FUNCTION Coolant flows through the engine, where it picks up heat. It then flows to the radiator, where the heat is given up to the outside air. The coolant continually recirculates through the cooling system, as illustrated in FIGURES 21–2 AND 21–3. COOLING SYSTEM OPERATION The temperature of the coolant rises as much as 15°F (8°C) as it goes through the engine and cools as it goes through the radiator. The coolant flow rate may be as high as 1 gallon (4 liters) per minute for each horsepower the engine produces. Hot coolant comes out of the thermostat housing on the top of the engine on most engines. The engine coolant outlet is connected
to the radiator by the upper radiator hose and clamps. The coolant in the radiator is cooled by air flowing through the radiator. As the coolant moves through the radiator, it cools. The cooler coolant leaves the radiator through an outlet and the lower radiator hose, and then flows to the inlet side of the water pump, where it is recirculated through the engine. NOTE: Some newer engine designs such as Chrysler’s 4.7 liter V-8 and General Motor’s 4.8, 5.3, 5.7, and 6.0 liter V-8s place the thermostat on the inlet side of the water pump. As the cooled coolant hits the thermostat, the thermostat closes until the coolant temperature again causes it to open. Placing the thermostat in the inlet side of the water pump therefore reduces the rapid temperature changes that could cause stress in the engine, especially if aluminum heads are used with a cast iron block. Radiators are designed for the maximum rate of heat transfer using minimum space. Cooling airflow through the radiator is aided by a belt- or electric motor–driven cooling fan.
THERMOSTATS PURPOSE AND FUNCTION There is a normal operating temperature range between low-temperature and high-temperature extremes. The thermostat controls the minimum normal temperature. The thermostat is a temperature-controlled valve placed at the engine coolant outlet on most engines. THERMOSTAT OPERATION An encapsulated wax-based plastic pellet heat sensor is located on the engine side of the thermostatic valve. As the engine warms, heat swells the heat sensor. SEE FIGURE 21–4. A mechanical link, connected to the heat sensor, opens the thermostat valve. As the thermostat begins to open, it allows some coolant to flow to the radiator, where it is cooled. The remaining part of the coolant continues to flow through the bypass, thereby bypassing the thermostat and flowing back through the engine. SEE FIGURE 21–5. The rated temperature of the thermostat indicates the temperature at which the thermostat starts to open. The thermostat is fully
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SPRING
PISTON
UPPER HOUSING
THERMOSTAT TEMPERATURE RATING
STARTS TO OPEN
FULLY OPEN
180°F
180°F
200°F
195°F
195°F
215°F
CHART 21–1 The temperature of the coolant depends on the rating of the thermostat.
LOWER HOUSING
COPPER CUP
WAX PELLET
FIGURE 21–4 A cross section of a typical wax-actuated thermostat showing the position of the wax pellet and spring.
COOLANT COLD FLOWS TO ENGINE THERMOSTAT CLOSED
FIGURE 21–6 A thermostat stuck in the open position caused the engine to operate too cold. If a thermostat is stuck closed, this can cause the engine to overheat.
BYPASS PASSAGE
(a) COOLANT HOT FLOWS TO RADIATOR THERMOSTAT OPEN
FIGURE 21–7 This internal bypass passage in the thermostat housing directs cold coolant to the water pump.
(b)
FIGURE 21–5 (a) When the engine is cold, the coolant flows through the bypass. (b) When the thermostat opens, the coolant can flow to the radiator.
open at about 20°F higher than its opening temperature. SEE CHART 21–1. If the radiator, water pump, and coolant passages are functioning correctly, the engine should always be operating within the opening and fully open temperature range of the thermostat. SEE FIGURE 21–6.
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NOTE: A bypass around the closed thermostat allows a small part of the coolant to circulate within the engine during warm-up. It is a small passage that leads from the engine side of the thermostat to the inlet side of the water pump. It allows some coolant to bypass the thermostat even when the thermostat is open. The bypass may be cast or drilled into the engine and pump parts. SEE FIGURES 21–7 AND 21–8. The bypass aids in uniform engine warm-up. Its operation eliminates hot spots and prevents the building of excessive coolant pressure in the engine when the thermostat is closed.
TECH TIP Do Not Take Out the Thermostat! Some vehicle owners and technicians remove the thermostat in the cooling system to “cure” an overheating problem. In some cases, removing the thermostat can cause overheating rather than stop it. This is true for three reasons.
FIGURE 21–8 A cutaway of a small block Chevrolet V-8 showing the passage from the cylinder head through the front of the intake manifold to the thermostat.
THERMOSTAT TESTING
There are three basic methods used to check the operation of the thermostat. 1. Hot water method. If the thermostat is removed from the vehicle and is closed, insert a 0.015 in. (0.4 mm) feeler gauge in the opening so that the thermostat will hang on the feeler gauge. The thermostat should then be suspended by the feeler gauge in a container of water or coolant along with a thermometer. The container should be heated until the thermostat opens enough to release and fall from the feeler gauge. The temperature at which the thermostat falls is the opening temperature of the thermostat. If it is within 5°F (4°C) of the temperature stamped on the thermostat, the thermostat is satisfactory for use. If the temperature difference is greater, the thermostat should be replaced. SEE FIGURE 21–9. 2. Infrared thermometer method. An infrared thermometer (also called a pyrometer) can be used to measure the temperature of the coolant near the thermostat. The area on the engine side of the thermostat should be at the highest temperature that exists in the engine. A properly operating cooling system should cause the pyrometer to read as follows: As the engine warms, the temperature reaches near thermostat opening temperature. As the thermostat opens, the temperature drops just as the thermostat opens, sending coolant to the radiator. As the thermostat cycles, the temperature should range between the opening temperature of the thermostat and 20°F (11°C) above the opening temperature. NOTE: If the temperature rises higher than 20°F (11°C) above the opening temperature of the thermostat, inspect the cooling system for a restriction or low coolant flow. A clogged radiator could also cause the excessive temperature rise. 3. Scan tool method. A scan tool can be used on many vehicles to read the actual temperature of the coolant as detected by the engine coolant temperature (ECT) sensor. Although the sensor or the wiring to and from the sensor may be defective, at least the scan tool can indicate what the computer “thinks” is the engine coolant temperature.
1. Without a thermostat the coolant can flow more quickly through the radiator. The thermostat adds some restriction to the coolant flow, and therefore keeps the coolant in the radiator longer. This also allows additional time for the heat transfer between the hot engine parts and the coolant. The presence of the thermostat thus ensures a greater reduction in the coolant temperature before it returns to the engine. 2. Heat transfer is greater with a greater difference between the coolant temperature and air temperature. Therefore, when coolant flow rate is increased (no thermostat), the temperature difference is reduced. 3. Without the restriction of the thermostat, much of the coolant flow often bypasses the radiator entirely and returns directly to the engine. If overheating is a problem, removing the thermostat will usually not solve the problem. Remember, the thermostat controls the temperature of the engine coolant by opening at a certain temperature and closing when the temperature falls below the minimum rated temperature of the thermostat.
THERMOMETER FEELER GAUGE
HEATER
FIGURE 21–9 Checking the opening temperature of a thermostat.
THERMOSTAT REPLACEMENT
Two important things about
a thermostat include: 1. An overheating engine may result from a faulty thermostat. 2. An engine that does not get warm enough always indicates a faulty thermostat.
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TOP TANK
RADIATOR CAP
TUBES
COOLANT FLOW
BOT TOM TANK
FIGURE 21–10 Some thermostats are an integral part of the housing. This thermostat and radiator hose housing is serviced as an assembly. Some thermostats snap into the engine radiator fill tube underneath the pressure cap.
TRANSMISSION OIL COOLER
TUBES
RADIATOR CAP
COOLING FIN
COOLANT FLOW FINS
TUBES TRANSMISSION OIL COOLER
FIGURE 21–11 The tubes and fins of the radiator core.
FIGURE 21–12 A radiator may be either a down-flow or a crossflow type. To replace the thermostat, coolant will have to be drained from the radiator drain petcock to lower the coolant level below the thermostat. It is not necessary to completely drain the system. The hose should be removed from the thermostat housing neck and then the housing removed to expose the thermostat. SEE FIGURE 21–10. The gasket flanges of the engine and thermostat housing should be cleaned, and the gasket surface of the housing must be flat. The thermostat should be placed in the engine with the sensing pellet toward the engine. Make sure that the thermostat position is correct, and install the thermostat housing with a new gasket or O-ring. CAUTION: Failure to set the thermostat into the recessed groove will cause the housing to become tilted when tightened. If this happens and the housing bolts are tightened, the housing will usually crack, creating a leak. The upper hose should then be installed and the system refilled. Install the correct size of radiator hose clamp.
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RADIATORS TYPES
The two types of radiator cores in common use in most vehicles are:
Serpentine fin core
Plate fin core
In each of these types, the coolant flows through oval-shaped core tubes. Heat is transferred through the tube wall and soldered joint to cooling fins. The fins are exposed to the air that flows through the radiator, which removes heat from the radiator and carries it away. SEE FIGURES 21–11 AND 21–12. Older automobile radiators were made from yellow brass. Since the 1980s, most radiators have been made from aluminum with nylon-reinforced plastic side tanks. These materials are corrosion resistant, have good heat transferability, and are easily formed.
TRANSMISSION FLUID COOLER
TECH TIP Working Better Under Pressure A problem that sometimes occurs with a high-pressure cooling system involves the water pump. For the pump to function, the inlet side of the pump must have a lower pressure than its outlet side. If inlet pressure is lowered too much, the coolant at the pump inlet can boil, producing vapor. The pump will then spin the coolant vapors and not pump coolant. This condition is called pump cavitation. Therefore, a radiator cap could be the cause of an overheating problem. A pump will not pump enough coolant if not kept under the proper pressure for preventing vaporization of the coolant.
FLUID LINES CROSSFLOW RADIATOR
FIGURE 21–13 Many vehicles equipped with an automatic transmission use a transmission fluid cooler installed in one of the radiator tanks.
Core tubes are made from 0.0045 to 0.012 in. (0.1 to 0.3 mm) sheet brass or aluminum, using the thinnest possible materials for each application. The metal is rolled into round tubes and the joints are sealed with a locking seam. The two basic designs of radiators include: 1. Down-flow radiators. This design was used mostly in older vehicles, where the coolant entered the radiator at the top and flowed downward, exiting the radiator at the bottom. 2. Cross-flow radiators. Most radiators use a cross-flow design, where the coolant flows from one side of the radiator to the opposite side.
PRESSURE CAPS OPERATION On most radiators the filler neck is fitted with a pressure cap. The cap has a spring-loaded valve that closes the cooling system vent. This causes cooling pressure to build up to the pressure setting of the cap. At this point, the valve will release the excess pressure to prevent system damage. Engine cooling systems are pressurized to raise the boiling temperature of the coolant.
The boiling temperature will increase by approximately 3°F (1.6°C) for each pound of increase in pressure. At sea level, water will boil at 212°F (100°C). With a 15 PSI (100 kPa) pressure cap, water will boil at 257°F (125°C), which is a maximum operating temperature for an engine.
FUNCTIONS
The specified coolant system temperature serves
two functions.
HOW RADIATORS WORK
The main limitation of heat transfer in a cooling system is in the transfer from the radiator to the air. Heat transfers from the water to the fins as much as seven times faster than heat transfers from the fins to the air, assuming equal surface exposure. The radiator must be capable of removing an amount of heat energy approximately equal to the heat energy of the power produced by the engine. Each horsepower is equivalent to 42 BTUs (10,800 calories) per minute. As the engine power is increased, the heat-removing requirement of the cooling system is also increased. With a given frontal area, radiator capacity may be increased by increasing the core thickness, packing more material into the same volume, or both. The radiator capacity may also be increased by placing a shroud around the fan so that more air will be pulled through the radiator. NOTE: The lower air dam in the front of the vehicle is used to help direct the air through the radiator. If this air dam is broken or missing, the engine may overheat, especially during highway driving due to the reduced airflow through the radiator. When a transmission oil cooler is used in the radiator, it is placed in the outlet tank, where the coolant has the lowest temperature. SEE FIGURE 21–13.
1. It allows the engine to run at an efficient temperature, close to 200°F (93°C), with no danger of boiling the coolant. 2. The higher the coolant temperature, the more heat the cooling system can transfer. The heat transferred by the cooling system is proportional to the temperature difference between the coolant and the outside air. This characteristic has led to the design of small, high-pressure radiators that are capable of handling large quantities of heat. For proper cooling, the system must have the right pressure cap correctly installed. A vacuum valve is part of the pressure cap and is used to allow coolant to flow back into the radiator when the coolant cools down and contracts. SEE FIGURE 21–14. NOTE: The proper operation of the pressure cap is especially important at high altitudes. The boiling point of water is lowered by about 1°F for every 550 ft increase in altitude. Therefore, in Denver, Colorado (altitude 5,280 ft), the boiling point of water is about 202°F, and at the top of Pike’s Peak in Colorado (14,110 ft) water boils at 186°F.
METRIC RADIATOR CAPS
According to the SAE Handbook, all radiator caps must indicate their nominal (normal) pressure rating. Most original equipment radiator caps are rated at about 14 to 16 PSI (97 to 110 kPa).
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VACUUM VALVE
OVERFLOW TUBE – COOLANT FLOW FROM RECOVE RY TANK
PRESSURE VALVE
OVERFLOW TUBE – COOLANT FLOW TO RECOVE RY TANK
VACUUM VALVE OPERATION
PRESSURE SPRING
GASKET
PRESSURE VALVE OPERATION
FIGURE 21–14 The pressure valve maintains the system pressure and allows excess pressure to vent. The vacuum valve allows coolant to return to the system from the recovery tank. However, many vehicles manufactured in Japan or Europe use radiator pressure indicated in a unit called a bar. One bar is the pressure of the atmosphere at sea level, or about 14.7 PSI. The conversions in CHART 21–2 can be used when replacing a radiator cap, to make certain it matches the pressure rating of the original. NOTE: Many radiator repair shops use a 7 PSI (0.5 bar) radiator cap on a repaired radiator. A 7 PSI cap can still provide boil protection of 21°F (3°F ⴛ 7 PSI ⴝ 21°F) above the boiling point of the coolant. For example, if the boiling point of the antifreeze coolant is 223°F, then 21°F is added for the pressure cap, and boilover will not occur until about 244°F (223°F ⴙ 21°F ⴝ 244°F). Even though this lower pressure radiator cap provides some protection and will also help protect the radiator repair, the coolant can still boil before the “hot” dash warning light comes on and, therefore, should not be used. In addition, the lower pressure in the cooling system could cause cavitation to occur and damage the water pump. For best results, always follow the vehicle manufacturer’s recommended radiator cap.
BAR OR ATMOSPHERES
POUNDS PER SQUARE INCH (PSI)
1.1
16
1.0
15
0.9
13
0.8
12
0.7
10
0.6
9
0.5
7
CHART 21–2 Comparison showing the metric pressure as shown on the top of the cap to pounds per square inch (PSI).
THERMOSTAT HEATER CONTROL VALVE
COOLANT RECOVERY SYSTEMS PURPOSE AND FUNCTION
Excess pressure usually forces some coolant from the system through an overflow. Most cooling systems connect the overflow to a plastic reservoir to hold excess coolant while the system is hot. SEE FIGURE 21–15. When the system cools, the pressure in the cooling system is reduced and a partial vacuum forms. This vacuum pulls the coolant from the plastic container back into the cooling system, keeping the system full. Because of this action, the system is called a coolant recovery system. A vacuum valve allows coolant to reenter the system as the system cools so that the radiator parts will not collapse under the partial vacuum.
SURGE TANK
Some vehicles use a surge tank, which is located at the highest level of the cooling system and holds about 1 quart (1 liter) of coolant. A hose attaches to the bottom of the surge tank to the inlet side of the water pump. A smaller bleed hose attaches
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PLASTIC EXPANSION TANK
HEATER CORE WATER PUMP RADIATOR CAP
FULL ADD
RADIATOR
CLOSED LINE CONNECTING RADIATOR TO EXPANSION TANK
FIGURE 21–15 The level in the coolant recovery system raises and lowers with engine temperature.
to the side of the surge tank to the highest point of the radiator. The bleed line allows some coolant circulation through the surge tank, and air in the system will rise below the radiator cap and be forced from the system if the pressure in the system exceeds the rating of the radiator cap. SEE FIGURE 21–16.
SCROLL
FIGURE 21–16 Some vehicles use a surge tank, which is located at the highest level of the cooling system, with a radiator cap.
FIGURE 21–17 Coolant flow through the impeller and scroll of a coolant pump for a V-type engine.
REAL WORLD FIX The Collapsed Radiator Hose Story An automotive student asked the automotive instructor what brand of radiator hose is the best. Not knowing exactly what to say, the instructor asked if there was a problem with the brand hose used. The student had tried three brands and all of them collapsed when the engine cooled. The instructor then explained that the vehicle needed a new pressure cap and not a new upper radiator hose. The student thought that because the lower hose did not collapse that the problem had to be a fault with the hose. The instructor then explained that the lower radiator hose has a spring inside to keep the lower hose from collapsing due to the lower pressure created at the inlet to the water pump. The radiator cap was replaced and the upper radiator hose did not collapse when the engine cooled.
WATER PUMPS OPERATION
The water pump (also called a coolant pump) is driven by one of two methods.
Crankshaft belt
Camshaft
Coolant recirculates from the radiator to the engine and back to the radiator. Low-temperature coolant leaves the radiator by the bottom outlet. It is pumped into the warm engine block, where it picks up some heat. From the block, the warm coolant flows to the hot cylinder head, where it picks up more heat. NOTE: Some engines use reverse cooling. This means that the coolant flows from the radiator to the cylinder head(s) before flowing to the engine block. Water pumps are not positive displacement pumps. The water pump is a centrifugal pump that can move a large volume of coolant without increasing the pressure of the coolant. The pump pulls coolant in at the center of the impeller. Centrifugal force throws the coolant outward so that it is discharged at the impeller tips. SEE FIGURE 21–17.
FIGURE 21–18 A demonstration engine running on a stand, showing the amount of coolant flow that actually occurs through the cooling system.
?
FREQUENTLY ASKED QUESTION
How Much Coolant Can a Water Pump Move? A typical water pump can move a maximum of about 7,500 gallons (28,000 liters) of coolant per hour, or recirculate the coolant in the engine over 20 times per minute. This means that a water pump could be used to empty a typical private swimming pool in an hour! The slower the engine speed, the less power is consumed by the water pump. However, even at 35 mph (56 km/h), the typical water pump still moves about 2,000 gallons (7,500 liters) per hour or 0.5 gallon (2 liters) per second! SEE FIGURE 21–18.
As engine speeds increase, more heat is produced by the engine and more cooling capacity is required. The pump impeller speed increases as the engine speed increases to provide extra coolant flow at the very time it is needed. Coolant leaving the pump impeller is fed through a scroll. The scroll is a smoothly curved passage that changes the fluid flow
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BEARING ASSEMBLY
SEAL
FIGURE 21–19 This severely corroded water pump could not circulate enough coolant to keep the engine cool. As a result, the engine overheated and blew a head gasket.
FIGURE 21–21 A cutaway of a typical water pump showing the long bearing assembly and the seal. The weep hole is located between the seal and the bearing. If the seal fails, then coolant flows out of the weep hole to prevent the coolant from damaging the bearing.
TECH TIP Release the Belt Tension Before Checking a Water Pump The technician should release water pump belt tension before checking for water pump bearing looseness. To test a water pump bearing, it is normal to check the fan for movement; however, if the drive belt is tight, any looseness in the bearing will not be felt. WEEP HOLE
FIGURE 21–20 The bleed weep hole in the water pump allows coolant to leak out of the pump and not be forced into the bearing. If the bearing failed, more serious damage could result.
direction with minimum loss in velocity. The scroll is connected to the front of the engine so as to direct the coolant into the engine block. On V-type engines, two outlets are often used, one for each cylinder bank. Occasionally, diverters are necessary in the water pump scroll to equalize coolant flow between the cylinder banks of a V-type engine in order to equalize the cooling.
WATER PUMP SERVICE A worn impeller on a water pump can reduce the amount of coolant flow through the engine. SEE FIGURE 21–19. If the seal of the water pump fails, coolant will leak out of the weep hole. The hole allows coolant to escape without getting trapped and forced into the water pump bearing assembly. SEE FIGURE 21–20. The hole allows coolant to escape without getting trapped and forced into the water pump bearing assembly. If the bearing is defective, the pump will usually be noisy and will have to be replaced. Before replacing a water pump that has failed because of a loose or noisy bearing, check all of the following: 1. Drive belt tension 2. Bent fan 3. Fan for balance
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If the water pump drive belt is too tight, excessive force may be exerted against the pump bearing. If the cooling fan is bent or out of balance, the resulting vibration can damage the water pump bearing. SEE FIGURE 21–21.
COOLANT FLOW IN THE ENGINE TYPES OF SYSTEMS
Coolant flows through the engine in one
of the following ways.
Parallel flow system. In the parallel flow system, coolant flows into the block under pressure and then crosses the head gasket to the head through main coolant passages beside each cylinder.
Series flow system. In the series flow system, the coolant flows around all the cylinders on each bank. All the coolant flows to the rear of the block, where large main coolant passages allow the coolant to flow across the head gasket. The coolant then enters the rear of the heads. In the heads, the coolant flows forward to a crossover passage on the intake manifold outlet at the highest point in the engine cooling passage. This is usually located at the front of the engine. The outlet is either on the heads or in the intake manifold.
FAN SHROUD CROSSFLOW RADIATOR
COOLANT PASSAGE
RADIATOR FAN SWITCH GAS VENT
AUTOMATIC TRANSMISSION OIL COOLER FITTINGS
FIGURE 21–22 A Chevrolet V-8 block that shows the large coolant holes and the smaller gas vent or bleed holes that must match the head gasket when the engine is assembled.
Series-parallel flow system. Some engines use a combination of these two coolant flow systems and call it a seriesparallel flow system. Any steam that develops will go directly to the top of the radiator. In series flow systems, bleed holes or steam slits in the gasket, block, and head perform the function of letting out the steam.
COOLANT FLOW AND HEAD GASKET DESIGN
Most V-type engines use cylinder heads that are interchangeable side to side, but not all engines. Therefore, based on the design of the cooling system and flow through the engine, it is very important to double check that the cylinder head is matched to the block and that the head gasket is installed correctly (end for end) so that all of the cooling passages are open to allow the proper flow of coolant through the system. SEE FIGURE 21–22.
COOLING FANS ELECTRONICALLY CONTROLLED COOLING FAN
ELECTRIC FAN BLADES FAN MOTOR
FIGURE 21–23 A typical electric cooling fan assembly showing the radiator and related components. Many rear-wheel-drive vehicles and all transverse engines drive the fan with an electric motor. SEE FIGURE 21–23. NOTE: Most electric cooling fans are computer controlled. To save energy, most cooling fans are turned off whenever the vehicle is traveling faster than 35 mph (55 km/h). The ram air caused by the vehicle speed is enough to keep the radiator cool. Of course, if the computer senses that the temperature is still too high, the computer will turn on the cooling fan, to “high,” if possible, in an attempt to cool the engine to avoid severe engine damage.
WARNING Some electric cooling fans can come on after the engine is off without warning. Always keep hands and fingers away from the cooling fan blades unless the electrical connector has been disconnected to prevent the fan from coming on. Always follow all warnings and cautions.
Two
types of electric cooling fans used on many engines include:
One two-speed cooling fan
Two cooling fans (one for normal cooling and one for high heat conditions)
The PCM commands low-speed fans on under the following conditions.
Engine coolant temperature (ECT) exceeds approximately 223°F (106°C).
A/C refrigerant pressure exceeds 190 PSI (1,310 kPa).
After the vehicle is shut off, the engine coolant temperature at key-off is greater than 284°F (140°C) and system voltage is more than 12 volts. The fan(s) will stay on for approximately three minutes.
The PCM commands the high-speed fan on under the following conditions.
Engine coolant temperature (ECT) reaches 230°F (110°C).
A/C refrigerant pressure exceeds 240 PSI (1,655 kPa).
Certain diagnostic trouble codes (DTCs) set.
To prevent a fan from cycling on and off excessively at idle, the fan may not turn off until the ignition switch is moved to the off position or the vehicle speed exceeds approximately 10 mph (16 km/h).
THERMOSTATIC FANS
On some rear-wheel-drive vehicles, a thermostatic cooling fan is driven by a belt from the crankshaft. It turns faster as the engine turns faster. Generally, the engine is required to produce more power at higher speeds. Therefore, the cooling system will also transfer more heat. Increased fan speed aids in the required cooling. Engine heat also becomes critical at low engine speeds in traffic where the vehicle moves slowly. The thermostatic fan is designed so that it uses little power at high engine speeds and minimizes noise. Two types of thermostatic fans include: 1. Silicone coupling. The silicone coupling fan drive is mounted between the drive pulley and the fan. HINT: When diagnosing an overheating problem, look carefully at the cooling fan. If silicone is leaking, then the fan may not be able to function correctly and should be replaced. 2. Thermostatic spring. A second type of thermal fan has a thermostatic spring added to the silicone coupling fan drive. The thermostatic spring operates a valve that allows the fan to freewheel when the radiator is cold. As the radiator warms to about 150°F (65°C), the air hitting the thermostatic spring will cause the spring to change its shape. The new shape of the
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HEATER HOSE CONNECTIONS
THERMOSTATIC SPRING
HEATER CORE
FIGURE 21–24 A typical engine-driven thermostatic spring cooling fan.
TECH TIP
FIGURE 21–25 A typical heater core installed in a heating, ventilation, and air-conditioning (HVAC) housing assembly.
STEP 1
After the engine has been operated, feel the upper radiator hose. If the engine is up to proper operating temperature, the upper radiator hose should be too hot to hold. The hose should also be pressurized. a. If the hose is not hot enough, replace the thermostat. b. If the hose is not pressurized, test or replace the radiator pressure cap if it will not hold the specified pressure. c. If okay, see step 2.
STEP 2
With the engine running, feel both heater hoses. (The heater should be set to the maximum heat position.) Both hoses should be too hot to hold. If both hoses are warm (not hot) or cool, check the heater control valve for proper operation (if equipped). If one hose is hot and the other (return) is just warm or cool, remove both hoses from the heater core or engine and flush the heater core with water from a garden hose.
STEP 3
If both heater hoses are hot and there is still a lack of heating concern, then the fault is most likely due to an airflow blend door malfunction. Check service information for the exact procedure to follow.
Be Sure to Always Use a Fan Shroud A fan shroud forces the fan to draw air through the radiator. If a fan shroud is not used, then air is drawn from around the fan and will reduce the airflow through the radiator. Many overheating problems are a result of not replacing the factory shroud after engine work or body repair work to the front of the vehicle.
spring opens a valve that allows the drive to operate like the silicone coupling drive. When the engine is very cold, the fan may operate at high speeds for a short time until the drive fluid warms slightly. The silicone fluid will then flow into a reservoir to let the fan speed drop to idle. SEE FIGURE 21–24. The fan is designed to move enough air at the lowest fan speed to cool the engine when it is at its highest coolant temperature. The fan shroud is used to increase the cooling system efficiency.
HEATER CORES PURPOSE AND FUNCTION Most of the heat absorbed from the engine by the cooling system is wasted. Some of this heat, however, is recovered by the vehicle heater. Heated coolant is passed through tubes in the small core of the heater. Air is passed across the heater fins and is then sent to the passenger compartment. In some vehicles, the heater and air conditioning work in series to maintain vehicle compartment temperature. SEE FIGURE 21–25.
HINT: Heat from the heater that “comes and goes” is most likely the result of low coolant level. Usually with the engine at idle, there is enough coolant flow through the heater. At higher engine speeds, however, the lack of coolant through the heads and block prevents sufficient flow through the heater.
COOLING SYSTEM TESTING VISUAL INSPECTION
HEATER PROBLEM DIAGNOSIS
When the heater does not produce the desired amount of heat, many owners and technicians replace the thermostat before doing any other troubleshooting. It is true that a defective thermostat is the reason for the engine not to reach normal operating temperature, but there are many other causes besides a defective thermostat that can result in lack of heat from the heater. To determine the exact cause, follow this procedure.
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Many cooling system faults can be found by performing a thorough visual inspection. Items that can be inspected visually include:
Water pump drive belt for tension or faults
Cooling fan for faults
Heater and radiator hoses for condition and leaks
Coolant overflow or surge tank coolant level
PRESSURE TESTER
ADAPTER
FIGURE 21–26 A heavily corroded radiator from a vehicle that was overheating. A visual inspection discovered that the corrosion had eaten away many of the cooling fins, yet did not leak. This radiator was replaced and it solved the overheating problem.
FIGURE 21–27 Pressure testing the cooling system. A typical handoperated pressure tester applies pressure equal to the radiator cap pressure. The pressure should hold; if it drops, this indicates a leak somewhere in the cooling system. An adapter is used to attach the pump to the cap to determine if the radiator can hold pressure, and release it when pressure rises above its maximum rated pressure setting.
Evidence of coolant loss
Radiator condition SEE FIGURE 21–26.
CAP
FIGURE 21–28 The pressure cap should be checked for proper operation using a pressure tester as part of the cooling system diagnosis.
FIGURE 21–29 Use dye specifically made for coolant when checking for leaks using a black light.
3. Radiator 4. Heater core
PRESSURE TESTING Pressure testing using a hand-operated pressure tester is a quick and easy cooling system test. The radiator cap is removed (engine cold!) and the tester is attached in the place of the radiator cap. By operating the plunger on the pump, the entire cooling system is pressurized. SEE FIGURE 21–27. CAUTION: Do not pump up the pressure beyond that specified by the vehicle manufacturer. Most systems should not be pressurized beyond 14 PSI (100 kPa). If a greater pressure is used, it may cause the water pump, radiator, heater core, or hoses to fail. If the cooling system is free from leaks, the pressure should stay and not drop. If the pressure drops, look for evidence of leaks anywhere in the cooling system, including: 1. Heater hoses 2. Radiator hoses
5. Cylinder head 6. Core plugs in the side of the block or cylinder head Pressure testing should be performed whenever there is a leak or suspected leak. The pressure tester can also be used to test the radiator cap. An adapter is used to connect the pressure tester to the radiator cap. Replace any cap that will not hold pressure. SEE FIGURE 21–28.
COOLANT DYE LEAK TESTING
One of the best methods to check for a coolant leak is to use a fluorescent dye in the coolant, one that is specifically designed for coolant. Operate the vehicle with the dye in the coolant until the engine reaches normal operating temperature. Use a black light to inspect all areas of the cooling system. When there is a leak, it will be easy to spot because the dye in the coolant will be seen as bright green. SEE FIGURE 21–29.
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REAL WORLD FIX Highway Overheating
FIGURE 21–30 When an engine overheats, often the coolant overflow container boils.
COOLANT TEMPERATURE WARNING LIGHT PURPOSE AND FUNCTION
Most vehicles are equipped with a heat sensor for the engine operating temperature indicator light. If the warning light comes on during driving (or the temperature gauge goes into the red danger zone), then the coolant temperature is about 250°F to 258°F (120°C to 126°C), which is still below the boiling point of the coolant (assuming a properly operating pressure cap and system). SEE FIGURE 21–30.
PRECAUTIONS
If the coolant temperature warning light comes on, follow these steps. STEP 1
Shut off the air conditioning and turn on the heater. The heater will help rid the engine of extra heat. Set the blower speed to high.
STEP 2
If possible, shut the engine off and let it cool. (This may take over an hour.)
STEP 3
Never remove the radiator cap when the engine is hot.
STEP 4
Do not continue to drive with the hot light on, or serious damage to your engine could result.
STEP 5
If the engine does not feel or smell hot, it is possible that the problem is a faulty hot light sensor or gauge. Continue to drive, but to be safe, stop occasionally and check for any evidence of overheating or coolant loss.
COMMON CAUSES OF OVERHEATING Overheating can be caused by defects in the cooling system, such as the following: 1. Low coolant level 2. Plugged, dirty, or blocked radiator 3. Defective fan clutch or electric fan 4. Incorrect ignition timing (if adjustable) 5. Low engine oil level 6. Broken fan drive belt 7. Defective radiator cap 8. Dragging brakes 9. Frozen coolant (in freezing weather)
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A vehicle owner complained of an overheating vehicle, but the problem occurred only while driving at highway speeds. The vehicle, equipped with a 4-cylinder engine, would run in a perfectly normal manner in city driving situations. The technician flushed the cooling system and replaced the radiator cap and the water pump, thinking that restricted coolant flow was the cause of the problem. Further testing revealed coolant spray out of one cylinder when the engine was turned over by the starter with the spark plugs removed. A new head gasket solved the problem. Obviously, the head gasket leak was not great enough to cause any problems until the engine speed and load created enough flow and heat to cause the coolant temperature to soar. The technician also replaced the oxygen (O2) sensor, because the IAT-type coolant contains phosphates and silicates that often contaminate the sensor. The deteriorated oxygen sensor could have contributed to the problem.
10. Defective thermostat 11. Defective water pump (the impeller slipping on the shaft internally) 12. Blocked cooling passages in the block or cylinder head(s)
COOLING SYSTEM INSPECTION COOLANT LEVEL
The cooling system is one of the most maintenance-free systems in the engine. Normal maintenance involves an occasional check on the coolant level. It should also include a visual inspection for signs of coolant system leaks and for the condition of the coolant hoses and fan drive belts. CAUTION: The coolant level should only be checked when the engine is cool. Removing the pressure cap from a hot engine will release the cooling system pressure while the coolant temperature is above its atmospheric boiling temperature. When the cap is removed, the pressure will instantly drop to atmospheric pressure level, causing the coolant to boil immediately. Vapors from the boiling liquid will blow coolant from the system. Coolant will be lost, and someone may be injured or burned by the high-temperature coolant that is blown out of the filler opening.
ACCESSORY DRIVE BELT TENSION
Drive belt condition and proper installation are important for the proper operation of the cooling system. There are four ways vehicle manufacturers specify that the belt tension is within factory specifications. 1. Belt tension gauge. A belt tension gauge is needed to achieve the specified belt tension. Install the belt and operate the engine with all of the accessories turned on, to run in the belt for at least five minutes. Adjust the tension of the accessory drive belt
torque needed to rotate the tensioner. If the torque reading is below specifications, the tensioner must be replaced. 4. Deflection. Depress the belt between the two pulleys that are the farthest apart and the flex or deflection should be 1/2 in. MARKS ON STATIONARY MOUNT
COOLING SYSTEM SERVICE FLUSHING COOLANT
Flushing the cooling system includes
the following steps. MARKS ON MOVABLE SECTION OF THE TENSIONER
FIGURE 21–31 Typical marks on an accessory drive belt tensioner.
Number of Ribs Used
Tension Range (lb.)
3
45 to 60
4
60 to 80
5
75 to 100
6
90 to 125
7
105 to 145
CHART 21–3 The number of ribs determines the tension range of the belt.
TECH TIP The Water Spray Trick Lower-than-normal alternator output could be the result of a loose or slipping drive belt. All belts (V and serpentine multigroove) use an interference angle between the angle of the Vs of the belt and the angle of the Vs on the pulley. A belt wears this interference angle off the edges of the V of the belt. As a result, the belt may start to slip and make a squealing sound even if tensioned properly. A common trick to determine if the noise is from the belt is to spray water from a squirt bottle at the belt with the engine running. If the noise stops, the belt is the cause of the noise. The water quickly evaporates and therefore, water just finds the problem—it does not provide a short-term fix.
STEP 1
Drain the system (dispose of the old coolant correctly).
STEP 2
Fill the system with clean water and flushing/cleaning chemical.
STEP 3
Start the engine until it reaches operating temperature with the heater on.
STEP 4
Drain the system and fill with clean water.
STEP 5
Repeat until drain water runs clear (any remaining flush agent will upset pH).
STEP 6
Fill the system with 50/50 antifreeze/water mix or premixed coolant.
STEP 7
Start the engine until it reaches operating temperature with the heater on.
STEP 8
Adjust coolant level as needed.
Bleeding the air out of the cooling system is important because air can prevent proper operation of the heater and can cause the engine to overheat. Use a clear hose attached to the bleeder valve and the other end in a “suitable” container. This prevents coolant from getting on the engine and gives the technician a visual clue as to the color of coolant. SEE FIGURE 21–32. Check service information for specific bleeding procedures and location of the air bleeder fittings.
COOLANT EXCHANGE MACHINE Many coolant exchange machines are able to perform one or more of the following operations.
Exchange old coolant with new coolant
Flush the cooling system
Pressure or vacuum check the cooling system for leaks
The use of a coolant exchange machine pulls a vacuum on the cooling system which helps illuminate air pockets from forming during coolant replacement. If an air pocket were to occur, the following symptoms may occur. 1. Lack of heat from the heater. Air rises and can form in the heater core, which will prevent coolant from flowing. 2. Overheating. The engine can overheat due to the lack of proper coolant flow through the system.
to factory specifications or use CHART 21–3 for an example of the proper tension based on the size of the belt. Replace any serpentine belt that has more than three cracks in any one rib that appears in a 3 in. span. 2. Marks on the tensioner. Many tensioners have marks that indicate the normal operating tension range for the accessory drive belt. Check service information for the location of the tensioner mark. SEE FIGURE 21–31. 3. Torque wrench reading. Some vehicle manufacturers specify that a beam-type torque wrench be used to determine the
Always follow the operating instructions for the coolant exchange machine being used. SEE FIGURE 21–33.
HOSE INSPECTION Coolant system hoses are critical to engine cooling. As the hoses get old, they become either soft or brittle and sometimes swell in diameter. Their condition depends on their material and on the engine service conditions. If a hose breaks while the engine is running, all coolant will be lost. A hose should be replaced any time it appears to be abnormal. SEE FIGURE 21–34.
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CHAFED OR BURNED
BLEEDER VALVE
SOFT AND SPONGY
(a) HARDENED
SWOLLEN OR OIL SOAKED
(b)
FIGURE 21–32 (a) Many vehicle manufacturers recommend that the bleeder valve be opened whenever refilling the cooling system. (b) Chrysler recommends that a clear plastic hose (1/4 in. ID) be attached to the bleeder valve and directed into a suitable container to keep from spilling coolant onto the ground and on the engine and to allow the technician to observe the flow of coolant for any remaining oil bubbles.
FIGURE 21–34 All cooling system hoses should be checked for wear or damage.
TECH TIP Always Replace the Pressure Cap Replace the old radiator cap with a new cap with the same pressure rating. The cap can be located on the following: 1. Radiator 2. Coolant recovery reservoir 3. Upper radiator hose
WARNING Never remove a pressure cap from a hot engine. When the pressure is removed from the system, the coolant will immediately boil and will expand upward, throwing scalding coolant in all directions. Hot coolant can cause serious burns.
HINT: To make hose removal easier and to avoid possible damage to the radiator, use a utility knife and slit the hose lengthwise. Then simply peel the hose off.
FIGURE 21–33 Using a coolant exchange machine helps eliminate the problem of air getting into the system which can cause overheating or lack of heat due to air pockets getting trapped in the system.
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The hose and hose clamp should be positioned so that the clamp is close to the bead on the neck. This is especially important on aluminum hose necks to avoid corrosion. When the hoses are in place and the drain petcock is closed, the cooling system can be refilled with the correct coolant mixture.
TECH TIP Always Use Heater Hoses Designed for Coolant Many heater hoses are sizes that can also be used for other purposes such as oil lines. Always check and use hose that states it is designed for heater or cooling system use. SEE FIGURE 21–35.
TECH TIP Quick and Easy Cooling System Problem Diagnosis 1. If overheating occurs in slow stop-and-go traffic, the usual cause is low airflow through the radiator. Check for airflow blockages or cooling fan malfunction. 2. If overheating occurs at highway speeds, the cause is usually a radiator or coolant circulation problem. Check for a restricted or clogged radiator.
DISPOSING OF USED COOLANT Used coolant drained from vehicles should be disposed of according to state or local laws. Some communities permit draining into the sewer. Ethylene glycol will easily biodegrade. There could be problems with groundwater contamination, however, if coolant is spilled on open ground. Check with recycling companies authorized by local or state governments for the exact method recommended for disposal in your area.
FIGURE 21–35 The top 3/8 in. hose is designed for oil and similar liquids, whereas the 3/8 in. hose below is labeled “heater hose” and is designed for coolant.
CLEANING THE RADIATOR EXTERIOR Overheating can result from exterior and interior radiator plugging. External plugging is caused by dirt and insects. This type of plugging can be seen if you look straight through the radiator while a light is held behind it. It is most likely to occur on off-road vehicles. The plugged exterior of the radiator core can usually be cleaned with water pressure from a hose. The water is aimed at the engine side of the radiator. The water should flow freely through the core at all locations. If this does not clean the core, the radiator should be removed for cleaning at a radiator shop.
REVIEW QUESTIONS 1. What is normal operating coolant temperature?
6. Explain the operation of a thermostatic cooling fan.
2. Explain the flow of coolant through the engine and radiator.
7. Describe how to diagnose a heater problem.
3. Why is a cooling system pressurized?
8. What are 10 common causes of overheating?
4. What is the purpose of the coolant system bypass? 5. Describe how to perform a drain, flush, and refill procedure on a cooling system.
CHAPTER QUIZ 1. The upper radiator collapses when the engine cools. What is the most likely cause? a. Defective upper radiator hose b. Missing spring from the upper radiator hose, which is used to keep it from collapsing c. Defective thermostat d. Defective pressure cap 2. What can be done to prevent air from getting trapped in the cooling system when the coolant is replaced? a. Pour the coolant into the radiator slowly. b. Use a coolant exchange machine that draws a vacuum on the system. c. Open the air bleeder valves while adding coolant. d. Either b or c
3. Heat transfer is improved from the coolant to the air when the ______________. a. Temperature difference is great b. Temperature difference is small c. Coolant is 95% antifreeze d. Both a and c 4. A water pump is a positive displacement type of pump. a. True b. False 5. Water pumps ______________. a. Only work at idle and low speeds and are disengaged at higher speeds b. Use engine oil as a lubricant and coolant c. Are driven by the engine crankshaft or camshaft d. Disengage during freezing weather to prevent radiator failure
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6. What diagnostic trouble code (DTC) could be set if the thermostat is defective? a. P0300 c. P0171 b. P0440 d. P0128 7. Which statement is true about thermostats? a. The temperature marked on the thermostat is the temperature at which the thermostat should be fully open. b. Thermostats often cause overheating. c. The temperature marked on the thermostat is the temperature at which the thermostat should start to open. d. Both a and b 8. Technician A says that the radiator should always be inspected for leaks and proper flow before installing a rebuilt engine. Technician B says that overheating during slow city driving can only be due to a defective electric cooling fan. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
chapter
9. A customer complains that the heater works sometimes, but sometimes only cold air comes out while driving. Technician A says that the water pump is defective. Technician B says that the cooling system could be low on coolant. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 10. The normal operating temperature (coolant temperature) of an engine equipped with a 195°F thermostat is ______________. a. 175°F to 195°F b. 185°F to 205°F c. 195°F to 215°F d. 175°F to 215°F
ENGINE OIL
22 OBJECTIVES: After studying Chapter 22, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “D” (Lubrication and Cooling Systems Diagnosis and Repair). • Describe the importance and the role of engine oil. • Describe the various oil specifications. • Discuss the importance of the vehicle manufacturer’s requirements. • Discuss how to change oil. KEY TERMS: Additive package 201 • American Petroleum Institute (API) 199 • Antidrainback valve 204 • Association des Constructeurs Européens d’Automobiles (ACEA) 200 • Bypass valve 204 • HTHS 201 • International Lubricant Standardization and Approval Committee (ILSAC) 200 • Japanese Automobile Standards Organization (JASO) 201 • Miscible 198 • Pour point 198 • SAPS 201 • Society of Automotive Engineers (SAE) 199 • Viscosity index (VI) 198 • zinc dialkyl dithiophosphate (ZDDP or ZDP) 202
INTRODUCTION Engine oil has a major effect on the proper operation and life of any engine. Engine oil provides the following functions in every engine.
Lubricates moving parts
Helps cool engine parts
Helps seal piston rings
Helps to neutralize acids created by the by-products of combustion
Reduces friction in the engine
Helps to prevent rust and corrosion
As a result of these many factors, the specified engine oil must be used and replaced at the specified mileage or time intervals.
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PROPERTIES OF ENGINE OIL The most important engine oil property is its thickness or viscosity.
As oil is cooled, it gets thicker.
As oil is heated, it gets thinner.
Therefore, its viscosity changes with temperature. The oil must not be too thick at low temperatures to allow the engine to start. The lowest temperature at which oil will pour is called its pour point. An index of the change in viscosity between the cold and hot extremes is called the viscosity index (VI). All oils with a high viscosity index thin less with heat than do oils with a low viscosity index. Oils must also be miscible, meaning they are capable of mixing with other oils (brands and viscosities, for example) without causing any problems such as sludge.
SAE RATING TERMINOLOGY Engine oils are sold with a Society of Automotive Engineers (SAE) grade number, which indicates the viscosity range into which the oil fits. Oils tested at 212°F (100°C) have a number with no letter following. For example, SAE 30 indicates that the oil has only been checked at 212°F (100°C). This oil’s viscosity falls within the SAE 30 grade number range when the oil is hot. Oils tested at 0°F (⫺18°C) are rated with a number and the letter W, which means winter and indicates that the viscosity was tested at 0°F, such as SAE 20W. MULTIGRADE ENGINE OIL
An SAE 5W-30 multigrade oil meets the SAE 5W viscosity specification when cooled to 0°F (⫺18°C), and meets the SAE 30 viscosity specification when tested at 212°F (100°C). Most vehicle manufacturers recommend the following multiviscosity engine oils.
SAE 5W-30
SAE 10W-30
SEE FIGURE 22–1. Oil with a high viscosity has a higher resistance to flow and is thicker than lower viscosity oil. Thick oil is not necessarily good oil and thin oil is not necessarily bad oil. Generally, the following items can be considered in the selection of engine oil within the recommended viscosity range.
Thinner oil 1. Improved cold engine starting 2. Improved fuel economy
Thicker oil 1. Improved protection at higher temperatures 2. Reduced fuel economy
NOTE: Always use the specified viscosity engine oil.
GY
NG
E
FIGURE 22–1 The SAE viscosity rating required is often printed on the engine oil filler cap.
SAE 5W-30
VI
EN
R
SN
API
RVICE E S
CONSE
R
FIGURE 22–2 API doughnut for a SAE 5W-30, SN engine oil. When compared to a reference oil, the “energy conserving” designation indicates a 1.1% better fuel economy for SAE 10W-30 oils and 0.5% better fuel economy for SAE 5W-30 oils.
API RATING DEFINITION
The American Petroleum Institute (API), working with the engine manufacturers and oil companies, has established an engine oil performance classification. Oils are tested and rated in production automotive engines. The oil container is printed with the API classification of the oil. The API performance or service classification and the SAE grade marking are the only information available to help determine which oil is satisfactory for use in an engine. SEE FIGURE 22–2 for a typical API oil container “doughnut.”
GASOLINE ENGINE RATINGS In gasoline engine ratings, the letter S means service, but can also indicate spark ignition engines. The rating system is open ended so that newer, improved ratings can be readily added as necessary (the letter I is skipped to avoid confusion with the number one). SA
Straight mineral oil (no additives), not suitable for use in any engine
SB
Nondetergent oil with additives to control wear and oil oxidation
SC
Obsolete (1964)
SD
Obsolete (1968)
SE
Obsolete (1972)
SF
Obsolete (1980)
SG
Obsolete (1988)
SH
Obsolete (1993–1997)
SJ
Obsolete (1997–2001)
SL
2001–2003
SM
2004–2010
SN
2011⫹
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REAL WORLD FIX The Case of the Wrong Oil Viscosity
•
D
AMERICAN
ER
STITUTE IN
“Oil pressure not reaching specified at 1250 RPM.”
FOR GASOLINE ENGINES
•C
A 2007 Dodge Durango 5.7 liter Hemi with a multiple displacement system (MDS) had the oil changed at a shop. SAE 10W-30 was used as this was the “standard” bulk oil in the shop. After the oil change, the vehicle was returned to the customer. Within a few minutes, however, the “check engine” light came on. The technician checked for diagnostic trouble codes (DTCs) and found a P0521 DTC stored. The technician checked service information and discovered that the code could be set if the incorrect viscosity engine oil had been used. The description of the P0521 read:
TROLEUM PE
TIFIE
FIGURE 22–3 The International Lubricant Standardization and Approval Committee (ILSAC) starburst symbol. If this symbol is on the front of the container of oil, then it is acceptable for use in almost any gasoline engine.
The technician changed the oil and used the specified SAE 5W-20, then cleared the DTC. A test drive confirmed that the change to the correct viscosity oil solved the problem.
TECH TIP Three Oil Change Facts Three facts that are important to know when changing oil are: 1. Recommended SAE viscosity (thickness) for the temperature range that is anticipated before the next oil change (such as SAE 5W-30) 2. Quality rating as recommended by the engine or vehicle manufacturer such as API SM and other specified rating such as the ILSAC and vehicle manufacturer’s specifications 3. Recommended oil change interval (time or mileage) (usually every 5,000 miles or every six months)
NOTE: Vehicles built since about 1996 that use roller valve lifers can use the newer, higher rated engine oil classifications where older, now obsolete ratings were specified. Newly overhauled antique cars or engines also can use the newer, improved oils, as the appropriate SAE viscosity grade is used for the anticipated temperature range. Engines older than an about 1996 or those using flat-bottom lifters should use a zinc additive if using newer rated oil.
DIESEL ENGINE RATINGS
Diesel classifications begin with the letter C, which stands for commercial, but can also indicate compression ignition or diesel engines.
owner and technician know that the oil is suitable for use in almost any gasoline engine. SEE FIGURE 22–3.
CA
Obsolete
CB
Obsolete
CC
Obsolete
The original GF-1 (gasoline fueled) rating in 1993
CD
Minimum rating for use in a diesel engine service
Updated to GF-2 in 1997
CE
Designed for certain turbocharged or supercharged heavy-duty diesel engine service
Updated to GF-3 in 2000
Updated to GF-4 in 2004
Updated to GF-5 in 2010
CF
ILSAC RATINGS
For off-road indirect injected diesel engine service
CF-2 Two-stroke diesel engine service CF-4 High-speed four-stroke cycle diesel engine service
For more information, visit www.gf-5.com.
CG-4 Severe-duty high-speed four-stroke diesel engine service CI-4
Severe-duty high-speed four-stroke diesel engine service
CJ-4
Required for use in all 2007 and newer diesels using ultra-low-sulfur diesel (ULSD) fuel
ILSAC OIL RATING
EUROPEAN OIL RATING SYSTEM DEFINITION
The Association des Constructeurs Européens d’Automobiles (ACEA) rates the oil according to the following:
DEFINITION The International Lubricant Standardization and Approval Committee (ILSAC) developed an oil rating that consolidates the SAE viscosity rating and the API quality rating. If an engine oil meets the standards, a “starburst” symbol is displayed on the front of the oil container. If the starburst is present, the vehicle
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Gasoline engine oils ACEA A1 Low-friction low-viscosity oil (not suitable for some engines) ACEA A2 General-purpose oil intended for normal oil change intervals; not suitable for some engines or extended oil drain intervals in any engine
ACEA RATINGS
FIGURE 22–4 ACEA ratings are included on the back of the oil container if it meets any of the standards. ACEA ratings apply to European vehicles only such as BMW, Mercedes, Audi, and VW. ACEA A3
ACEA A4 ACEA A5
Designed for high-performance engines and/or extended oil drain intervals and under all temperature ranges Designed to meet the requirements for gasoline direct injection (GDI) engines Low-viscosity low-friction oil not suitable for some engines
FIGURE 22–5 Viscosity index (VI) improver is a polymer and feels like finely ground foam rubber. When dissolved in the oil, it expands when hot to keep the oil from thinning.
JAPANESE OIL RATINGS The Japanese Automobile Standards Organization (JASO) also publishes oil standards. The JASO tests use small Japanese engines, and their ratings require more stringent valve train wear standards than oil ratings in other countries. However, most Japanese brand vehicles specify SAE, API, and ILSAC rating standards for use in the engine.
Diesel engine oils ACEA B1
ACEA B2
ACEA B3
ACEA B4
ACEA B5 ACEA C1,
Low-viscosity oil designed for use in a passenger vehicle diesel engine that is equipped with an indirect injection system; not suitable for some diesel engines Designed for use in passenger vehicle diesel engines using indirect injection and using normal oil drain intervals Intended for use in a high-performance indirect injected passenger vehicle diesel engine and under extended oil drain interval conditions Intended for year-round use in direct injected passenger vehicle diesel engines; can be used in an indirect injected diesel engine Designed for extended oil drain intervals; not suitable for some engines Specifications for catalyst compatible oils, C2, C3 which have limits on the amount of sulfur, zinc, and other additives that could harm the catalytic converter
Starting in 2004, the ACEA began using combined ratings such as A1/B1, A3/B3, A3/B4, and A5/B5.
ACEA oil also requires low levels of sulfated ash, phosphorous, and sulfur, abbreviated SAPS, and has a high temperature/high shear rate viscosity, abbreviated HTHS.
C ratings are catalytic converter compatible oils and include: C1: basically A5/B5 oil with low SAPS, low HTHS C2: A5/B5 with low HTHS and mid-level SAPS C3: A5/B5 with high HTHS and mid-level SAPS C4: low SAPS; high HTHS SEE FIGURE 22–4.
ENGINE OIL ADDITIVES Oil producers are careful to check the compatibility of the oil additives they use. A number of chemicals that will help each other can be used for each of the additive requirements. The balanced additives are called an additive package.
ADDITIVES TO IMPROVE THE BASE OIL
Viscosity index (VI) improver. Modifies the viscosity of the base fluid so that it changes less as the temperature rises; allows the lubricant to operate over a wider temperature range ( SEE FIGURE 22–5.)
Pour point depressant. Keeps the lubricant flowing at low temperatures
Antifoam agents. Foam reduces the effectiveness of a lubricant. The antifoam agents reduce/stop foaming when the oil is agitated or aerated.
ADDITIVES TO PROTECT THE BASE OIL
Antioxidants. Slow the breakdown of the base fluid caused by oxygen (air) and heat (Oxidation is the main cause of lubricant degradation in service.)
Oxidants. Prevent acid formation (corrosion) in the form of sludges, varnishes
Total base number (TBN). The reserve alkalinity used to neutralize the acids created during the combustion process (Typical TBN levels are between 60 and 100, which is dependent on the fuel sulfur level. The higher the sulfur percentage in the fuel, the higher the TBN required. The higher the total base
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TECH TIP Dirty Engine Oil Can Cause Oil Burning Service technicians have known for a long time that some of their customers never change the engine oil. Often these customers believe that because their engine uses oil and they add a new quart every week, they are doing the same thing as changing the oil. But dirty, oxidized engine oil could cause piston rings to stick and not seal the cylinder. Therefore, when the oil and filter are changed, the clean oil may free the piston rings, especially if the vehicle is driven on a long trip during which the oil is allowed to reach the normal operating temperature. An engine that is mechanically sound, but burning oil, may be “fixed” by simply changing the oil and filter.
number of oil, the longer it can be used in an engine. Long-life oils usually have higher total base numbers than other oils.)
ADDITIVES TO PROTECT THE ENGINE
Rust inhibitor. Inhibits the action of water on ferrous metal such as steel
Corrosion inhibitor. Protects nonferrous metals such as copper
Antiwear additive. Forms a protective layer on metal surfaces to reduce friction and prevent wear when no lubricant film is present
Extreme pressure additive. Functions only when heavy loads and temperatures are occurring
OIL BRAND COMPATIBILITY Many technicians and vehicle owners have their favorite brand of engine oil. The choice is often made as a result of marketing and advertising, as well as comments from friends, relatives, and technicians. If your brand of engine oil is not performing up to your expectations, then you may wish to change brands. For example, some owners experience lower oil pressure with a certain brand than they do with other brands with the same SAE viscosity rating.
Most experts agree that the oil changes are the most important regularly scheduled maintenance for an engine.
It is also wise to check the oil level regularly and add oil when needed.
According to SAE standard J-357, all engine oils must be miscible (compatible) with all other brands of engine oil.
Therefore, any brand of engine oil can be used as long as it meets the viscosity and API standards recommended by the vehicle manufacturer. Even though many people prefer a particular brand, be assured that, according to API and SAE, any major brand name engine oil can be used.
FIGURE 22–6 Using a zinc additive is important when using SM or SN-rated oil in an engine equipped with a flat-bottom lifter, especially during the break-in period.
?
FREQUENTLY ASKED QUESTION
Can Newer Engine Oils Be Used in Engines That Use Flat-Bottom Lifters No. Newer oil standards are designed to reduce phosphates in the engine oil that may leak past piston rings and end up in the exhaust system. These additives found in oil can then damage the catalytic converter. The levels of phosphate and zinc, commonly referred to as zinc dialkyl dithiophosphate (ZDDP or ZDP), have been reduced because they can cause damage to the catalytic converter. Even though engines consume very little oil, if the oil contains zinc, the efficiency of the catalytic converter is reduced. The use of ZDDP was intended to reduce sliding friction in an engine. Sliding friction is usually found in engines that use flat-bottom lifters. Most, if not all, engines produced over the past 15 years have used roller lifters or cam followers, so using the new oil without ZDDP is not a concern. Even diesel oils have reduced amounts of the zinc, so many camshaft manufacturers are recommending the use of an additive. Older oils had up to 0.15% ZDDP and now SM-rated oils list the zinc at just 0.08% or 800 parts per million. • Engine oil had about 1,200 ppm zinc prior to 2001. • In 2001, the zinc was reduced to 1,000 ppm; and in 2005, reduced again to the current 800 ppm. • API ratings do not specify the zinc content, just oil performance. If driving a vehicle with flat-bottom lifters, use engine oil specifically designed for older engines, such as Shell Rotella T, or use an additive, such as General Motor’s engine oil supplement (EOS), part number 1052367 or 88862586, or a zinc additive. Check with camshaft manufacturers for their recommended oil or additive to use. SEE FIGURE 22–6.
SYNTHETIC OIL DEFINITION Synthetic engine oils have been available for years for military, commercial, and general public use. The term synthetic means that it is a manufactured product and not refined from a naturally occurring substance, as engine oil (petroleum base) is
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refined from crude oil. Synthetic oil is processed from several different base stocks using several different methods.
API GROUPS According to the American Petroleum Institute, engine oil is classified into the following groups.
SAE 5W-30 SYNTHETIC OIL
SAE 5W-30 MINERAL (NON-SYNTHETIC) OIL
FIGURE 22–7 Mobil 1 synthetic engine oil is used by several vehicle manufacturers in new engines.
Group I. Mineral, nonsynthetic base oil with few if any additives; suitable for light lubricating needs and rust protection, not for use in an engine
Group II. Mineral oil with quality additive packages; includes most conventional engine oils
Group III. Hydrogenated (hydroisomerized) synthetic compounds commonly referred to as hydrowaxes or hydrocracked oil; the lowest costing synthetic engine oil; includes Castrol Syntec
Group IV. Synthetic oils made from mineral oil and monomolecular oil called polyalpholefin (POA); includes Mobil 1 ( SEE FIGURE 22–7.)
FIGURE 22–8 Both oils have been cooled to ⫺20°F (⫺29°C). Notice that the synthetic oil on the left flows more freely than the mineral oil on the right even though both are SAE 5W-30. TECH TIP Use Synthetic Engine Oil in Lawn and Garden Equipment Most four-cycle lawn and garden equipment engines are air cooled and operate hotter than many liquid-cooled engines. Lawn mowers and other small engines are often operated near or at maximum speed and power output for hours at a time. These operating conditions are hard on any engine oil. Try using synthetic oil. The cost is not as big a factor because most small four-cycle lawn mower engines require only about 1/2 quart (1/2 liter) of oil. The synthetic oil is able to perform under high temperatures better than conventional mineral oils.
Group V. Nonmineral sources such as alcohol from corn called diesters or polyolesters; includes Red Line synthetic oil
Groups III, IV, and V are considered to be synthetic because the molecular structure of the finished product does not occur naturally, but is man-made through chemical processes. All synthetic engine oils perform better than group II (mineral) oils, especially when tested according to the Noack Volatility Test ASTM D-5800. This test procedure measures the ability of an oil to stay in grade after it has been heated to 300°F (150°C) for one hour. The oil is then measured for percentage of weight loss. As the lighter components boil off, the oil’s viscosity will increase.
ADVANTAGES OF SYNTHETICS
The major advantage of using synthetic engine oil is its ability to remain fluid at very low temperatures. SEE FIGURE 22–8. This characteristic of synthetic oil makes it popular in colder climates where cold-engine cranking is important.
VEHICLE MANUFACTURER–SPECIFIC OIL SPECIFICATIONS The oil used should meet the specifications of the vehicle manufacturer, which include the following:
BMW Longlife-98 and longlife-01 (abbreviated LL-01), LL-04
General Motors GM 6094M
DISADVANTAGES OF SYNTHETICS
The major disadvantage is cost. The cost of synthetic engine oils can be four to five times the cost of petroleum-based engine oils.
GM 4718M (synthetic oil specification) Dexos 1 (all GM gasoline engines, 2011⫹) Dexos 2 (all GM diesel engines, 2011⫹)
SYNTHETIC BLENDS
A synthetic blend indicates that some synthetic oil is mixed with petroleum base engine oil; however, the percentage of synthetic used in the blend is unknown.
Ford WSS-M2C153-H WSS-M2C929-A (low viscosity rating, SAE 5W-20) WSS-M2C930-A
VEHICLE-SPECIFIC SPECIFICATIONS
WSS-M2C931-A WSS-M2C934-A
Chrysler MS-6395 (2005⫹ vehicles) MS-10725 (2004 and older)
BACKGROUND
Some oils can meet industry specifications, such as SAE, API, and/or ILSAC ratings, but not pass the tests specified by the vehicle manufacturer.
Honda/Acura HTO-06 (turbocharged engine only)
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OIL DRAIN-BACK VALVE
FIGURE 22–9 European vehicle manufacturers usually specify engine oil with a broad viscosity range, such as SAE 5W-40, and their own unique standards, such as the Mercedes specification 229.51. Always use the oil specified by the vehicle manufacturer.
Mercedes 229.3, 229.5, 229.1, 229.3, 229.31, 229.5, and 229.51 ( SEE FIGURE 22–9.)
Volkswagen (VW and Audi)
502.00, 505.00, 505.01, 503, 503.01, 505, 506 diesel, 506.1 diesel, and 507 diesel Be sure to use the oil that meets all of the specifications, especially during the warranty period. NOTE: Most Asian brand vehicle manufacturers do not specify any specifications other than SAE, API, and ILSAC. These vehicles include:
Acura/Honda
Toyota/Lexus/Scion
Kia
Hyundai
Nissan/Infinity
Mitsubishi
Mazda
Suzuki
HIGH MILEAGE OILS DEFINITION A “high mileage oil” is sold for use in vehicles that have over 75,000 miles and are, therefore, nearing the eight-year, 80,000-mile catalytic converter warranty period. Usually higher viscosity and lack of friction-reducing additives mean that most high mileage oils cannot meet ILSAC GF-4 rating and are, therefore, not recommended for use in most engines. DIFFERENCES
Esters are added to swell oil seals (main and valve-stem seals).
The oil is used only in engines with higher than 75,000 miles.
The oil usually does not have the energy rating of conventional oils (i.e., will not meet the specifications for use according to the owner manual in most cases).
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FIGURE 22–10 A rubber diaphragm acts as an antidrainback valve to keep the oil in the filter when the engine is stopped and the oil pressure drops to zero.
OIL FILTERS CONSTRUCTION The oil within the engine is pumped from the oil pan through the filter before it goes into the engine lubricating system passages. The filter is made from either closely packed cloth fibers or a porous paper. Large particles are trapped by the filter. Microscopic particles will flow through the filter pores. These particles are so small that they can flow through the bearing oil film and not touch the surfaces, so they do no damage. OIL FILTER VALVES Many oil filters are equipped with an antidrainback valve that prevents oil from draining out of the filter when the engine is shut off. SEE FIGURE 22–10. This valve keeps oil in the filter and allows the engine to receive immediate lubrication as soon as the engine starts. Either the engine or the filter is provided with a bypass valve that will allow the oil to go around the filter element. SEE FIGURE 22–11. The bypass allows the engine to be lubricated with dirty oil, rather than having no lubrication, if the filter becomes plugged. The oil also goes through the bypass when the oil is cold and thick. OIL FILTER DISPOSAL
Oil filters should be crushed and/ or drained of oil before discarding. After the oil has been drained, the filter can usually be disposed of as regular metal scrap. Always check and follow local, state, or regional oil filter disposal rules, regulations, and procedures. SEE FIGURE 22–12.
OIL CHANGE INTERVALS
All vehicle and engine manufacturers recommend a maximum oil change interval. The recommended intervals are almost always expressed in terms of mileage or elapsed time (or hours of operation), whichever milestone is reached first. Most vehicle manufacturers recommend an oil change interval of 7,500 to 12,000 miles (12,000 to 19,000 km) or every six months. If,
?
FREQUENTLY ASKED QUESTION
Why Change Oil If the Oil Filter Can Trap All the Dirt? Many persons believe that oil filters will remove all dirt from the oil being circulated through the filtering material. Most oil filters will filter particles that are about 10 to 20 microns in size. A micron is one-millionth of a meter or 0.000039 in. Most dirt and carbon particles that turn engine oil black are less than a micron in size. In other words, it takes about 3 million of these carbon particles to cover a pin head. To help visualize the smallness of a micron, consider that a typical human hair is 60 microns in diameter. In fact, anything smaller than 40 microns is not visible to the human eye. The dispersants added to engine oil prevent dirt from adhering together to form sludge. It is the same dispersant additive that prevents dirt from being filtered or removed by other means. If an oil filter could filter particles down to 1 micron, it would be so restrictive that the engine would not receive sufficient oil through the filter for lubrication. Oil recycling companies use special chemicals to break down the dispersants, which permit the dirt in the oil to combine into larger units that can be filtered or processed out of the oil.
FIGURE 22–11 A cutaway of a typical spin-on oil filter. Engine oil enters the filter through the small holes around the center of the filter and flows through the pleated paper filtering media and out the large hole in the center of the filter. The center metal cylinder with holes is designed to keep the paper filter from collapsing under the pressure. The bypass valve can be built into the center on the oil filter or is part of the oil filter housing and located in the engine.
OIL LIFE MONITORS Most vehicles built since the mid-1990s are equipped with a warning light that lets the driver know when the engine oil should be changed. The two basic types of oil change monitoring systems include:
FIGURE 22–12 A typical filter crusher. The hydraulic ram forces out most of the oil from the filter. The oil is trapped underneath the crusher and is recycled. however, any one of the conditions in the following list exists, the oil change interval recommendation drops to a more reasonable 2,000 to 3,000 miles (3,000 to 5,000 km) or every three months. The important thing to remember is that these are recommended maximum intervals and they should be shortened substantially if any of the following operating conditions exist.
Mileage only. The service light will come on based on mileage only and may include a service “A” or “B” based on what service needs to be performed. The interval can be every 3,750 to 7,500 miles, or even longer in some cases where specialized engine oil is required.
Algorithm. Computer programs contain algorithms that specify instructions a computer should perform (in a specific order) to carry out a task. This program uses the number of cold starts, the run time of the engine, and inputs from the engine coolant temperature (ECT) sensor to determine when the oil should be changed.
SEE FIGURE 22–13.
OIL CHANGE PROCEDURE STEP 1
Check the oil level on the dipstick before hoisting the vehicle. Document the work order and notify the owner if the oil level is low before changing the oil.
STEP 2
Safely hoist the vehicle.
STEP 3
Position a drain pan under the drain plug, then remove the plug with care to avoid contact with hot oil.
1. Operating in dusty areas 2. Towing a trailer
CAUTION: Used engine oil has been determined to be harmful. Rubber gloves should be worn to protect the skin. If used engine oil gets on the skin, wash thoroughly with soap and water.
3. Short-trip driving, especially during cold weather (The definition of a short trip varies among manufacturers, but it is usually defined as 4 to 15 miles (6 to 24 km) each time the engine is started.) 4. Operating in temperatures below freezing (32°F, 0°C)
STEP 4
Allow the oil to drain freely so that the contaminants come out with the oil. It is not critically important to get every last drop of oil from the engine oil pan, because a quantity of used oil still remains in the engine oil passages and oil pump.
STEP 5
While the engine oil is draining, the oil plug gasket should be examined. If it appears to be damaged, it should be replaced.
5. Operating at idle speed for extended periods of time (such as normally occurs in police or taxi service) Because most vehicles driven during cold weather are driven on short trips, technicians and automotive experts recommend changing the oil every 2,000 to 3,000 miles or every two to three months, whichever occurs first.
An oil change includes the following
steps.
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FIGURE 22–13 Many vehicle manufacturers can display the percentage of oil life remaining, whereas others simply turn on a warning lamp when it has been determined that an oil change is required.
(a)
TECH TIP Follow the Seasons Vehicle owners often forget when they last changed the oil. This is particularly true of the person who owns or is responsible for several vehicles. A helpful method for remembering when the oil should be changed is to change it at the start of each season of the year. • • • •
Fall (September 21) Winter (December 21) Spring (March 21) Summer (June 21)
Remembering that the oil needs to be changed on these dates helps owners budget for the expense and the time needed.
(b)
FIGURE 22–14 (a) A pick is pushed through the top of an oil filter that is positioned vertically. (b) When the pick is removed, a small hole allows air to get into the top of the filter which then allows the oil to drain out of the filter and back into the engine. TECH TIP
TECH TIP Change Oil Every Friday? The Pick Trick Removing an oil filter that is installed upside down can be a real mess. When this design filter is loosened, oil flows out from around the sealing gasket. To prevent this from happening, use a pick to poke a hole in the top of the filter, as shown in FIGURE 22–14. This small hole allows air to get into the filter, thereby allowing the oil to drain back into the engine rather than remain in the filter. After punching a hole in the filter, be sure to wait several minutes to allow time for the trapped oil to drain down into the engine before loosening the filter.
NOTE: Honda/Acura recommends that the oil drain plug gasket be replaced at every oil change on many of their vehicles. The aluminum sealing gasket does not seal once it has been tightened. Always follow the vehicle manufacturer’s recommendations. STEP 6
206
When the oil stops running and starts to drip, reinstall and tighten the drain plug. Replace the oil filter.
CHAPTER 2 2
A vehicle less than one year old came back to the dealer for some repair work. While writing the repair order, the service advisor noted that the vehicle had 88,000 miles on the odometer and was, therefore, out of warranty for the repair. Because the owner approved the repair anyway, the service advisor asked how he had accumulated so many miles in such a short time. The owner said that he was a traveling salesperson with a territory of “east of the Mississippi River.” Because the vehicle looked to be in new condition, the technician asked the salesperson how often he had the oil changed. The salesperson smiled and said proudly, “Every Friday.” Many fleet vehicles put on over 2,000 miles per week. How about changing their oil based on the time since last changed instead of by mileage?
STEP 7
Refill the engine with the proper type, grade, and quantity of oil. Restart the engine and allow the engine to idle until it develops oil pressure; then check the engine for leaks, especially at the oil filter.
OIL CHANGE
1
Before entering the customer’s car for the first time, be sure to install a seat cover as well as a steering wheel cover to protect the vehicle’s interior.
2
Run the engine until it is close to operating temperature. This will help the used oil drain more quickly and thoroughly.
3
Raise the vehicle on a hoist, and place the oil drain container in position under the oil drain plug. Be sure to wear protective gloves.
4
Remove the plug and allow the hot oil to drain from the engine. Use caution during this step as hot oil can cause painful burns!
5
While the engine oil continues to drain, remove the engine oil filter using a filter wrench. Some oil will drain from the filter, so be sure to have the oil drain container underneath when removing it.
6
Compare the new oil filter with the old one to be sure that it is the correct replacement.
CONTINUED
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OIL CHANGE
(CONTINUED)
7
The wise service technician adds oil to the oil filter whenever possible. This provides faster filling of the filter during start-up and a reduced amount of time that the engine does not have oil pressure.
9
Clean the area where the oil filter gasket seats to be sure that no part of the gasket remains that could cause an oil leak if not fully removed.
11 208
Carefully inspect the oil drain plug and gasket. Replace the gasket as needed. Install the drain plug and tighten firmly but do not overtighten!
CHAPTER 2 2
8
Apply a thin layer of clean engine oil to the gasket of the new filter. This oil film will allow the rubber gasket to slide and compress as the oil filter is being tightened.
10
Install the new oil filter and tighten it by hand. Do not use an oil filter wrench to tighten the filter! Most filters should be tightened 3/4 of a turn after the gasket contacts the engine.
12
Lower the vehicle and clean around the oil fill cap before removing it.
STEP BY STEP
13
15
17
Use a funnel to add the specified amount of oil to the engine at the oil fill opening. When finished, replace the oil fill cap.
Stop the engine and let it sit for a few minutes to allow the oil to drain back into the oil pan. Look underneath the vehicle to check for any oil leaks at the oil drain plug(s) or oil filter.
Reinstall the oil-level dipstick. Remove the dipstick a second time and read the oil level.
14
Start the engine and allow it to idle while watching the oil pressure gauge and/or oil pressure warning lamp. Oil pressure should be indicated within 15 seconds of starting the engine.
16
Remove the oil-level dipstick and wipe it clean with a shop cloth.
18
The oil level should be between the MIN and the MAX lines. In this case, the oil level should be somewhere in the cross-hatched area of the dipstick.
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REVIEW QUESTIONS 1. What property of oil does the SAE ratings reflect?
3. Why is the oil filter bypassed when the engine oil is cold and thick?
2. List the vehicle manufacturer’s oil specifications.
4. What are the steps in performing an oil change?
CHAPTER QUIZ 1. The “W” in SAE 5W-20 means ______________. a. Weight c. With b. Winter d. Without 2. Oil change intervals as specified by the vehicle manufacturer ______________. a. Are maximum time and mileage intervals b. Are minimum time and mileage intervals c. Only include miles driven between oil changes d. Generally only include time between oil changes 3. Most conventional (mineral) oil is made from what API group? a. Group I c. Group III b. Group II d. Group IV or V 4. Which rating is the ACEA rating specified for use by many European vehicle manufacturers? a. SAE c. SM b. A3/B3 d. GF-4 5. Technician A says that the engine oil used should meet the vehicle manufacturer’s standards. Technician B says that the specified viscosity of oil be used. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 6. Technician A says that some vehicle manufacturers recommend an ILSAC grade be used in the engine. Technician B says that an oil with the specified API rating and SAE viscosity rating should be used in an engine. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
chapter
23
7. Two technicians are discussing oil filters. Technician A says that the oil will remain perfectly clean if just the oil filter is changed regularly. Technician B says that oil filters can filter particles smaller than the human eye can see. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 8. The purpose of the oil filter bypass valve is to ______________. a. Allow oil to bypass the filter if the filter becomes clogged b. Keep the oil from draining out of the filter when the engine is off and the oil pressure drops to zero c. Allows oil to bypass the oil filter when the oil is hot, to help cool the oil d. Both a and b 9. Different brands of oil can be used in a vehicle from one oil change to another if they meet the vehicle specifications, because all oil is ______________. a. The same API group b. Miscible c. Of the same viscosity d. Both a and c 10. Older engines that use flat-bottom lifers should use oil (or an additive) that has enough ______________. a. Viscosity b. ZDDP (zinc) c. Polyalpholefin (POA) d. Diesters
LUBRICATION SYSTEM OPERATION AND DIAGNOSIS
OBJECTIVES: After studying Chapter 23, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “D” (Lubrication and Cooling Systems Diagnosis and Repair). • Explain hydrodynamic lubrication. • Describe how the oil pump and engine lubrication work. • Discuss how oil flows to the valve train components. • Explain how to inspect an oil pump for wear. KEY TERMS: Boundary lubrication 211 • Cavitate 213 • Dry sump 217 • Gallery 215 • Gerotor 213 • Hydrodynamic lubrication 211 • Positive displacement pumps 212 • Pressure regulating valve 213 • Sump 217 • Wet sump 217 • Windage tray 217
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OIL FEED MOVING SURFACE
WEDGE-SHAPED OIL FILM STATIONARY SURFACE
OIL MOLECULES
FIGURE 23–1 Oil molecules cling to metal surfaces but easily slide against each other. BLOCK MOVEMENT OIL FILM
FIGURE 23–2 Wedge-shaped oil film developed below a moving block.
INTRODUCTION Engine oil is the lifeblood of any engine. The purposes of a lubrication system include the following: 1. Lubricating all moving parts to prevent wear 2. Helping to cool the engine 3. Helping to seal piston rings 4. Cleaning, and holding dirt in suspension in the oil until it can be drained from the engine 5. Neutralizing acids that are formed as the result of the combustion process 6. Reducing friction 7. Preventing rust and corrosion
LUBRICATION PRINCIPLES PURPOSE AND FUNCTION Lubrication between two moving surfaces results from an oil film that separates the surfaces and supports the load. SEE FIGURE 23–1. Although oil does not compress, it does leak out around the oil clearance between the shaft and the bearing. In some cases, the oil film is thick enough to keep the surfaces from seizing, but can allow some contact to occur. This condition is called boundary lubrication. The specified oil viscosity and oil clearances must be adhered to during service to help prevent boundary lubrication and wear from occurring, which usually happens when the engine is under a heavy load and low speeds. The movement of the shaft helps prevent contact with the bearing. If oil were put on a flat surface and a heavy block were pushed across the surface, the block would slide more easily than if it were pushed across a dry surface. The reason for this is that a wedge-shaped oil film is built up between the moving block and the surface, as illustrated in FIGURE 23–2.
FIGURE 23–3 Wedge-shaped oil film curved around a bearing journal.
HYDRODYNAMIC LUBRICATION This wedging action is called hydrodynamic lubrication, and depends on the force applied to the rate of speed between the objects and the thickness of the oil. Thickness of oil is called the viscosity, and is defined as the ability of the oil to resist flow. High-viscosity oil is thick and low-viscosity oil is thin.
The prefix hydro- refers to liquids, as in hydraulics.
The term dynamic refers to moving materials.
Hydrodynamic lubrication occurs when a wedge-shaped film of lubricating oil develops between two surfaces that have relative motion between them. SEE FIGURE 23–3. The engine oil pressure system feeds a continuous supply of oil into the lightly loaded part of the bearing oil clearance. Hydrodynamic lubrication takes over as the shaft rotates in the bearing to produce a wedge-shaped hydrodynamic oil film that is curved around the bearing. The pressure between the bearings and the crankshaft can exceed 1,000 PSI (6,900 kPa) due to hydrodynamic lubrication, as created by the wedging action between the bearing and the crankshaft journal. Most bearing wear occurs during the initial start-up, and continues until a hydrodynamic film is established.
ENGINE LUBRICATION SYSTEMS PURPOSE AND FUNCTION
The primary function of the engine lubrication system is to maintain a positive and continuous oil supply to the bearings. Engine oil pressure must be high enough to get the oil to the bearings with enough force to cause the oil flow that is required for proper cooling.
NORMAL OIL PRESSURE The normal engine oil pressure range is from 10 to 60 PSI (200 to 400 kPa) or 10 PSI per 1000 engine RPM. It is normal to see the following:
Higher oil pressure when the engine is cold due to the oil being cold and at a higher viscosity
Lower oil pressure when the engine is at normal operating temperature due to the oil becoming thinner even though it is multiviscosity oil
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CAMSHAFT DISTRIBUTOR SHAFT
DRIVE GEAR FOR DISTRIBUTOR AND OIL PUMP
OIL PUMP
FIGURE 23–4 The dash oil pressure gauge may be a good indicator of engine oil pressure. If there is any concern about the oil pressure, always use a mechanical gauge to be sure.
FIGURE 23–5 An oil pump driven by the camshaft.
INLET
Lower oil pressures at idle and higher pressures at higher engine speeds because oil pumps are “positive displacement” pumps
The relatively low engine oil pressures obviously could not support these high bearing loads without hydrodynamic lubrication. Oil pressure measurements only show the oil pump pressure and not the pressure created between the bearings and the crankshaft journal due to hydrodynamic forces. SEE FIGURE 23–4.
OIL TEMPERATURE
Excessive temperatures, either too low or too high, are harmful to any engine. If the oil is too cold, it could be too thick to flow through the oil passages and lubricate all engine parts. If the oil is too hot, it could become too thin to provide the film strength necessary to prevent metal-to-metal contact and wear. Estimated oil temperature can be determined with the following formula. Estimated oil temperature ⴝ Outside air temperature ⴙ 120°F For example, 90°F outside air temperature ⫹ 120°F ⫽ 210°F estimated oil temperature. During hard acceleration (or high-power demand activities such as trailer towing), the oil temperature will quickly increase. Oil temperature should not exceed 300°F (150°C).
OIL PUMPS
PUMP BODY
OUTLET
FIGURE 23–6 In an external gear-type oil pump, the oil flows through the pump around the outside of each gear. This is an example of a positive displacement pump, wherein everything entering the pump must leave the pump.
The oil pump is driven from the end of the distributor shaft, often with a hexagon-shaped shaft. Some engines have a short shaft with a gear that meshes with the cam gear to drive both the distributor and oil pump. With a distributor-driven oil pump, the pump turns at one-half engine speed. On crankshaft-driven oil pump systems, the oil pump assembly is often made as part of the engine’s front cover so that it turns at the same speed as the crankshaft.
TYPES OF OIL PUMPS
All oil pumps are called positive displacement pumps, and each rotation of the pump delivers the same volume of oil; therefore, everything that enters must exit. Also a positive displacement pump will deliver more oil and higher pressure as the speed of the pump increases. Most automotive engines use one of two types of oil pumps, either gear or rotor.
PURPOSE AND FUNCTION
All production automobile engines have a full-pressure oil system. The oil pump is required to:
Provide 3 to 6 gallons per minute of engine oil to lubricate the engine
Maintain pressure, by forcing the oil into the lubrication system under pressure
PARTS AND OPERATION
In most engines that use a distributor, the distributor drive gear meshes with a gear on the camshaft, as shown in FIGURE 23–5.
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External gear type. A gear-type oil pump is usually driven by a shaft from the distributor, which is driven by the camshaft. As a result, this type of pump rotates at half engine (crankshaft) speed. The gear-type oil pump consists of two spur gears in a close-fit housing—one gear is driven while the other idles. As the gear teeth come out of mesh, they tend to leave a space, which is filled by oil drawn through the pump inlet. When the pump is pumping, oil is carried around the outside of each gear in the space between the gear teeth and the housing. As the teeth mesh in the center, oil is forced from the teeth into an oil passage, thus producing oil pressure. SEE FIGURE 23–6.
FIGURE 23–9 Gerotor-type oil pump driven by the crankshaft.
CALIBRATED SPRING
EXCESS PRESSURE
PISTON
FIGURE 23–7 A typical internal/external oil pump mounted in the front cover of the engine that is driven by the crankshaft.
INNER ROTOR OUTER ROTOR
INLET
OUTLET
POINT 1
CLOSED
OPEN
FIGURE 23–10 Oil pressure relief valves are spring loaded. The stronger the spring tension, the higher the oil pressure.
A
B
C
A. OIL IS PICKED UP IN LOBE OF OUTER ROTOR. B. OIL IS MOVED IN LOBE OF OUTER ROTOR TO OUTLET. C. OIL IS FORCED OUT OF OUTLET BECAUSE THE INNER AND OUTER ROTORS MESH TOO TIGHTLY AT POINT 1 AND THE OIL CANNOT PASS THROUGH.
FIGURE 23–8 The operation of a rotor-type oil pump.
Internal/external gear type. This type of oil pump is driven by the crankshaft and operates at engine speed. In this style of oil pump, two gears and a crescent stationary element are used. SEE FIGURE 23–7.
Rotor type. This rotor-type oil pump is driven by the crankshaft and uses a special lobe-shape gear meshing with the inside of a lobed rotor. The center lobed section is driven and the outer section idles. As the lobes separate, oil is drawn in just as it is drawn into gear-type pumps. As the pump rotates, it carries oil around and between the lobes. As the lobes mesh, they force the oil out from between them under pressure in the same manner as the gear-type pump. The pump is sized so that it will maintain a pressure of at least 10 PSI (70 kPa) in the oil gallery when the engine is hot and idling. Pressure will increase because the engine-driven pump also rotates faster. SEE FIGURE 23–8.
Gerotor type. This type of positive displacement oil pump uses an inner and an outer rotor. The term is derived from two words: “generated rotor,” or gerotor. The inner rotor has one fewer teeth than the outer rotor and both rotate. SEE FIGURE 23–9.
OIL PRESSURE REGULATION
In engines with a full-pressure lubricating system, maximum pressure is limited with a pressure
relief valve. The relief valve (sometimes called the pressure regulating valve) is located at the outlet of the pump. The relief valve controls maximum pressure by bleeding off oil to the inlet side of the pump. SEE FIGURE 23–10. The relief valve spring tension determines the maximum oil pressure. If a pressure relief valve is not used, the engine oil pressure will continue to increase as the engine speed increases. Maximum pressure is usually limited to the lowest pressure that will deliver enough lubricating oil to all engine parts that need to be lubricated. The oil pump is made so that it is large enough to provide pressure at low engine speeds and small enough that it will not cavitate at high speed. Cavitation occurs when the pump tries to pull oil faster than it can flow from the pan to the pickup. When it cannot get enough oil, it will pull air. This puts air pockets or cavities in the oil stream. A pump is cavitating when it is pulling air or vapors. NOTE: The reason for sheet metal covers over the pickup screen is to prevent cavitation. Oil is trapped under the cover, which helps prevent the oil pump from drawing in air, especially during sudden stops or during rapid acceleration. After the oil leaves the pump, it first flows through the oil filter and then is delivered to the moving parts through drilled oil passages. SEE FIGURE 23–11.
FACTORS AFFECTING OIL PRESSURE
Oil pressure can only be produced when the oil pump has a capacity larger than all the “leaks” in the engine.
Leaks. The leaks are the clearances at end points of the lubrication system. The end points are at the edges of bearings, the rocker arms, the connecting rod spit holes, and so on. These clearances are designed into the engine and are necessary for its proper operation. As the engine parts wear
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HYDRAULIC VALVE LIFTER (CAM FOLLOWER) OIL OIL RETURNS GALLERIES
OVERHEAD CAMSHAFT
PRESSURE OILING TO CRANKSHAFT, CAMSHAFT, AND ROCKER ARMS
SPLASH OILING AND RETURN TO SUMP
CAMSHAFT
FILTER BYPASS VALVE
SPLASH OILING TO CYLINDER WALLS
OIL FILTER
OIL PUMP CRANKSHAFT = GRAVITY RETURN = PRESSURE
FILTER FEED GALLERY
CRANKSHAFT
PICKUP TUBE AND SCREEN
END VIEW
SIDE VIEW
FIGURE 23–11 A typical engine design that uses both pressure and splash lubrication. Oil travels under pressure through the galleries (passages) to reach the top of the engine. Other parts are lubricated as the oil flows back down into the oil pan or is splashed onto parts.
?
FREQUENTLY ASKED QUESTION
Is a High-Pressure or High-Volume Oil Pump Needed? No. Engine parts need pressure after the oil reaches the parts that are to be lubricated. The oil film between the parts is developed and maintained by hydrodynamic lubrication. Excessive oil pressure requires more horsepower and provides no better lubrication than the minimum effective pressure. A high-volume pump is physically larger and pumps more oil with each revolution. A high-volume pump is used mostly in race engines where the main and rod bearing clearances are much greater than normal and therefore would need a great volume of oil to make up for the oil leaking from the wide clearances.
Viscosity of the engine oil. The viscosity of the oil affects both the pump capacity and the oil leakage. Thin oil or oil of very low viscosity slips past the edges of the pump and flows freely from the leaks. Hot oil has a low viscosity, and therefore, a hot engine often has low oil pressure. Cold oil is more viscous (thicker) than hot oil. This results in higher pressures, even with the cold engine idling. High oil pressure occurs with a cold engine, because the oil relief valve must open farther to release excess oil than is necessary with a hot engine. This larger opening increases the spring compression force, which in turn increases the oil pressure. Putting higher viscosity oil in an engine will raise the engine oil pressure to the regulated setting of the relief valve at a lower engine speed.
OIL PUMP CHECKS
The cover is removed to check the condi-
tion of the oil pump.
and clearance becomes greater, more oil will leak out. In other words, worn main or rod bearings are often the cause of lower than normal oil pressure.
Oil pump capacity. The oil pump must supply extra oil for any leaks. The capacity of the oil pump results from its size, rotating speed, and physical condition. When the pump is rotating slowly as the engine idles, oil pump capacity is low. If the leaks are greater than the pump capacity, engine oil pressure is low. As the engine speed increases, the pump capacity increases and the pump tries to force more oil out of the leaks. This causes the pressure to rise until it reaches the regulated maximum pressure. NOTE: A clogged oil pump pickup screen can cause lower than normal oil pressure because the amount of oil delivered by the pump is reduced by the clogged screen.
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Visual inspection. The gears and housing are examined for scoring. If the gears and housing are heavily scored, the entire pump should be replaced. SEE FIGURE 23–12.
Measurements. If they are lightly scored, the clearances in the pump should be measured. These clearances include the space between the gears and housing, the space between the teeth of the two gears, and the space between the side of the gear and the pump cover. A feeler gauge is often used to make these measurements. Gauging plastic can be used to measure the space between the side of the gears and the cover. The oil pump should be replaced when excessive clearance or scoring is found.
On most engines, the oil pump should be replaced as part of any engine work, especially if the cause for the repair is lack of lubrication. NOTE: The oil pump is the “garbage pit” of the entire engine. Any and all debris is often forced through the gears and housing of an oil pump. SEE FIGURE 23–13.
(a)
(a)
(b)
FIGURE 23–12 (a) A visual inspection indicated that this pump cover was worn. (b) An embedded particle of something was found on one of the gears, making this pump worthless except for scrap metal.
Always refer to the manufacturer’s specifications when checking the oil pump for wear. Typical oil pump clearances include the following: 1. End plate clearance: 0.0015 in. (0.04 mm) 2. Side (rotor) clearance: 0.012 in. (0.30 mm)
(b)
FIGURE 23–13 (a) The oil pump is the only part in an engine that gets unfiltered engine oil. The oil is drawn up from the bottom of the oil pan and is pressurized before flowing to the oil filter. (b) If debris gets into an oil pump, the drive or distributor shaft can twist and/or break. When this occurs, the engine will lose all oil pressure.
OIL PASSAGES
3. Rotor tip clearance: 0.010 in. (0.25 mm) 4. Gear end play clearance: 0.004 in. (0.10 mm) All parts should also be inspected closely for wear. Check the relief valve for scoring and check the condition of the spring. When installing the oil pump, coat the sealing surfaces with engine assembly lubricant. This lubricant helps draw oil from the oil pan on initial start-up.
PURPOSE AND FUNCTION
Oil from the oil pump first flows through the oil filter then goes through a drilled hole that intersects with a drilled main oil gallery, or longitudinal header. This is a long hole drilled from the front of the block to the back.
Inline engines use one oil gallery.
V-type engines may use two or three galleries.
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Passages drilled through the block bulkheads allow the oil to go from the main oil gallery to the main and cam bearings. SEE FIGURE 23–14. In some engines, oil goes to the cam bearings first, and then to the main bearings. It is important that the oil holes in the bearings match with the drilled passages in the bearing saddles so that the TECH TIP The New Hemi Engine Oiling System
bearing can be properly lubricated. Over a long period of use, bearings will wear. This wear causes excess clearance. The excess clearance will allow too much oil to leak from the side of the bearing. When this happens, there will be little or no oil left for bearings located farther downstream in the lubricating system. This is a major cause of bearing failure. To aid in bearing failure diagnosis, on most engines, the last rod bearing to receive oil pressure is typically the bearing farthest from the oil pump. If this bearing fails, then suspect low oil pressure as the probable cause.
VALVE TRAIN LUBRICATION
The oil gallery may intersect or have drilled passages to the valve lifter bores to lubricate the lifters. When hydraulic lifters are used, the oil pressure in the gallery keeps refilling them. On some engines, oil from the lifters goes up the center of a hollow pushrod to lubricate the pushrod ends, the rocker arm pivot, and the valve stem tip. In other engines, an oil passage is drilled from either the gallery or a cam bearing to the block deck, where it matches with a head gasket hole and a hole drilled in the head to carry the oil to a rocker arm shaft. Some engines use an enlarged bolt hole to carry lubrication oil around the rocker shaft cap screw to the rocker arm shaft.
The Chrysler Hemi V-8 engine uses a unique oiling system because the valve lifters are fed oil from the top of the cylinder heads and through the pushrods. While it is normal to have oil flowing through hollow pushrods, it is unique that in the Hemi V-8 the oil flows backward from normal and from the head down the hollow pushrods to the lifters. Be sure to use the specified viscosity of oil, as this is critical for proper lubrication of the valve lifters.
BEARING CAP CAVITY
JET HOLE CAMSHAFT LUBRICATION
CYLINDER AND OIL GALLERY CYLINDER HEAD OIL GALLERY
CAMSHAFT JOURNAL SLOT
HYDRAULIC LIFTERS
TURBOCHARGER LUBRICATION (IF EQUIPPED)
RESTRICTOR
MAIN GALLERY
BALANCE SHAFT GALLERY
OIL PUMP INTERMEDIATE SHAFT
FIGURE 23–14 An intermediate shaft drives the oil pump on this overhead camshaft engine. Note the main gallery and other drilled passages in the block and cylinder head.
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OIL DRAINBACK HOLES
FIGURE 23–15 Oil is sent to the rocker arms on this Chevrolet V-8 engine through the hollow pushrods. The oil returns to the oil pan through the oil drainback holes in the cylinder head. Holes in the bottom of the rocker arm shaft allow lubrication of the rocker arm pivot. Rocker arm assemblies need only a surface coating of oil, so the oil flow to the rocker assembly is minimized using restrictions or metered openings. The restriction or metering disk is in the lifter when the rocker assembly is lubricated through the pushrod. Oil that seeps from the rocker assemblies is returned to the oil pan through drain holes. These oil drain holes are often placed so that the oil drains on the camshaft or cam drive gears to lubricate them. Oil drain holes can be either machined or cast into the cylinder heads and block. SEE FIGURE 23–15. Some engines have means of directing a positive oil flow to the cam drive gears or chain. This may include either of the following:
Nozzle
Chamfer on a bearing parting surface, which allows oil to spray on the loaded portion of the cam drive mechanism
OIL PANS
BUILT-IN WINDAGE TRAY
FIGURE 23–16 A typical oil pan with a built-in windage tray used to keep oil from being churned up by the rotating crankshaft.
?
FREQUENTLY ASKED QUESTION
Why Is It Called a Windage Tray? A windage tray is a plate or baffle installed under the crankshaft and is used to help prevent aeration of the oil. Where does the wind come from? Pistons push air down into the crankcase as they move from top dead center to bottom dead center. The pistons also draw air and oil upward when moving from bottom dead center to top dead center. At high engine speeds, this causes a great deal of airflow, which can easily aerate the oil. Therefore, a windage tray is used to help prevent this movement of air (wind) from affecting the oil in the pan. Try the following: • Take an oil pan and add a few quarts (liters) of oil. • Then take an electric hair dryer and use it to blow air into the oil pan. Oil will be thrown everywhere, which helps illustrate why windage trays are used in all newer engines.
PURPOSE AND FUNCTION
The oil pan is where engine oil is used for lubricating the engine. Another name for the oil pan is a sump. As the vehicle accelerates, brakes, or turns rapidly, the oil tends to move around in the pan. Pan baffles and oil pan shapes are often used to keep the oil inlet under the oil at all times. As the crankshaft rotates, it acts like a fan and causes air within the crankcase to rotate with it. This can cause a strong draft on the oil, churning it so that air bubbles enter the oil, which then causes oil foaming. Oil with air will not lubricate like liquid oil, so oil foaming can cause bearings to fail. A baffle or windage tray is sometimes installed in engines to eliminate the oil churning problem. This may be an added part, as shown in FIGURE 23–16, or it may be a part of the oil pan. Windage trays have the good side effect of reducing the amount of air disturbed by the crankshaft, so that less power is drained from the engine at high crankshaft speeds.
DRY SUMP SYSTEM CONSTRUCTION AND OPERATION
The term sump is used to describe a location where oil is stored or held. In most engines, oil is held in the oil pan and the oil pump draws the oil from the
bottom. This type of system is called a wet sump oil system. In a dry sump system, the oil pan is shallow and the oil is pumped into a remote reservoir. In this reservoir, the oil is cooled and any trapped air is allowed to escape before being pumped back to the engine. A dry sump system uses an externally mounted oil reservoir.
ADVANTAGES
The advantages of a dry sump system are as
follows: 1. A shallow oil pan allows the engine to be mounted lower in the vehicle to improve cornering. 2. The oil capacity can be greatly expanded because the size of the reservoir is not limited. A larger quantity of oil means that the oil temperature can be controlled. 3. A dry sump system allows the vehicle to corner and brake for long periods, which is not able to be done with a wet sump system due to the oil being thrown to one side and away from the oil pickup. 4. A dry sump system also allows the engine to develop more power as the oil is kept away from the moving crankshaft.
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MAIN PRESSURE SUCTION
VALVE LIFTER
OIL COOLER
RETURN TO OIL TANK CAM BEARING OIL COOLER CRANK BEARING
OIL FILTER
OIL TANK OIL PUMP
FIGURE 23–18 Oil is cooled by the flow of coolant through the oil filter adapter. RELIEF VALVE OIL FILTER
OIL PICKUP
FIGURE 23–17 A dry sump system as used in a Chevrolet Corvette.
DISADVANTAGES
A dry sump system has the following
disadvantages. 1. The system is expensive as it requires components and plumbing not needed in a wet sump system. 2. The system is complex because the plumbing and connections, plus the extra components, result in more places where oil leaks can occur and change the way routine maintenance is handled. A dry sump oil system is used in most motor sport vehicles and is standard on certain high-performance production vehicles, such as some models of the Chevrolet Corvette, Porsche, and BMW. SEE FIGURE 23–17.
OIL COOLERS Oil temperature must be controlled on many high-performance or turbocharged engines. A larger capacity oil pan helps to control oil temperature. Some engines use remote mounted oil coolers. Coolant flows through the oil cooler to help warm the oil when the engine is cold and cool the oil when the engine is hot. Oil temperature should be:
Above 212°F (100°C) to boil off any accumulated moisture
Below 280°F to 300°F (138°C to 148°C)
?
FREQUENTLY ASKED QUESTION
What Is Acceptable Oil Consumption? There are a number of opinions regarding what is acceptable oil consumption. Most vehicle owners do not want their engine to use any oil between oil changes even if they do not change it more often than every 7,500 miles (12,000 km). Engineers have improved machining operations and piston ring designs to help eliminate oil consumption. Many stationary or industrial engines are not driven on the road, so they do not accumulate miles but still may consume excessive oil. A general rule for “acceptable” oil consumption is that it should be about 0.002 to 0.004 pound per horsepower per hour. To figure, use the following: 1.82 ⴛ Quarts used ⴝ Pound/hp/hr Operating hp ⴛ Total hours Therefore, oil consumption is based on the amount of work an engine performs. Although the formula may not be viable for vehicle engines used for daily transportation, it may be for the marine or industrial engine builder. Generally, oil consumption that is greater than 1 quart for every 600 miles (1 liter per 1,000 km) is considered to be excessive with a motor vehicle.
SEE FIGURE 23–18.
REVIEW QUESTIONS 1. What causes a wedge-shaped film to form in the oil? 2. What is hydrodynamic lubrication?
4. Describe how the oil flows from the oil pump, through the filter and main engine bearings, to the valve train.
3. Explain why internal engine leakage affects oil pressure.
5. What is the purpose of a windage tray?
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CHAPTER QUIZ 1. Normal oil pump pressure in an engine is ______________ PSI. a. 3 to 7 c. 100 to 150 b. 10 to 60 d. 180 to 210
6. What type of oil pump is driven by the crankshaft? a. Gerotor c. External gear b. Internal/external gear d. Both a and b
2. Two technicians are discussing oil pumps. Technician A says that many oil pumps are driven directly off the front of the crankshaft. Technician B says that some are driven from the distributor if the engine uses a distributor-type ignition system. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
7. Lower than specified oil pressure is measured on a high mileage engine. Technician A says that worn main or rod bearings could be the cause. Technician B says that a clogged oil pump pickup screen could be the cause. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
3. A typical oil pump can pump how many gallons per minute? a. 3 to 6 gallons b. 6 to 10 gallons c. 10 to 60 gallons d. 50 to 100 gallons 4. In typical engine lubrication systems, what components are the last to receive oil and the first to suffer from a lack of oil or oil pressure? a. Main bearings c. Valve train components b. Rod bearings d. Oil filters 5. Hydrodynamic lubrication is created by the wedging action of oil between the crankshaft journal and the bearing, can be as high as ______________ PSI. a. 60 c. 500 b. 120 d. 1,000
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24
8. Oil passages in an engine block are usually called ______________. a. Galleries c. Runners b. Holes d. Pathways 9. Why is a dry sump system used in some high-performance vehicles? a. It allows the vehicle to corner or brake for long periods b. It allows the engine to develop more power c. It allows for a greater oil capacity so that oil temperatures can be controlled d. All of the above 10. An engine oil cooler uses what to cool the oil? a. Coolant b. Air c. Air-conditioning evaporator output d. Automatic transmission fluid after it flows through the radiator
INTAKE AND EXHAUST SYSTEMS
OBJECTIVES: After studying Chapter 24, the reader should be able to: • Prepare for ASE Engine Performance (A8) certification test content area “C” (Air Induction and Exhaust Systems Diagnosis and Repair). • Discuss the purpose and function of intake air system components. • Explain the differences between throttle-body fuel-injection manifolds and port fuel-injection manifolds. • List the materials used in exhaust manifolds and exhaust systems. • Describe the purpose and function of the exhaust system components. KEY TERMS: EGR 223 • Hangers 226 • Helmholtz resonator 221 • Micron 220 • Plenum 223
AIR INTAKE FILTRATION
1. Clean the air before it is mixed with fuel 2. Silence intake noise 3. Act as a flame arrester in case of a backfire
NEED FOR AIR FILTERING
Gasoline must be mixed with air to form a combustible mixture. Air movement into an engine occurs due to low pressure (vacuum) being created in the engine. SEE FIGURE 24–1. Air contains dirt and other materials that cannot be allowed to reach the engine. Just as fuel filters are used to clean impurities from gasoline, an air cleaner and filter are used to remove contaminants from the air. The three main jobs of the air cleaner and filter include:
The automotive engine uses about 9,000 gallons (34,000 liters) of air for every gallon of gasoline burned at an air-fuel ratio of 14.7:1 by weight. Without proper filtering of the air before it enters the engine, dust and dirt in the air can seriously damage engine parts and shorten engine life. Abrasive particles can cause wear any place inside the engine where two surfaces move against each other, such as piston rings against the cylinder wall. The dirt particles then pass by the piston rings and into the crankcase. From the crankcase, the particles
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INTAKE VALVE
ATMOSPHERIC PRESSURE LOW PRESSURE (VACUUM)
THROTTLE BODY
PISTON
CRANKSHAFT
MAF SENSOR
FIGURE 24–1 Downward movement of the piston lowers the air pressure inside the combustion chamber. The pressure differential between the atmosphere and the inside of the engine forces air into the engine.
FIGURE 24–3 Most air filter housings are located on the side of the engine compartment and use flexible rubber hose to direct the airflow into the throttle body of the engine. time intervals are based on so-called normal driving. More frequent air filter replacement is necessary when the vehicle is driven under dusty, dirty, or other severe conditions. It is best to replace a filter element before it becomes too dirty to be effective. A dirty air filter that passes contaminants can cause engine wear.
FIGURE 24–2 Dust and dirt in the air are trapped in the air filter so they do not enter the engine. circulate throughout the engine in the oil. Large amounts of abrasive particles in the oil can damage other moving engine parts. The filter that cleans the intake air is in a two-piece air cleaner housing made either of:
Stamped steel or
Composite (usually nylon reinforced plastic) materials.
AIR FILTER ELEMENTS
The paper air filter element is the most common type of filter. It is made of a chemically treated paper stock that contains tiny passages in the fibers. These passages form an indirect path for the airflow to follow. The airflow passes through several fiber surfaces, each of which traps microscopic particles of dust, dirt, and carbon. Most air filters are capable of trapping dirt and other particles larger than 10 to 25 microns in size. One micron is equal to 0.000039 in.
NOTE: A person can only see objects that are 40 microns or larger in size. A human hair is about 50 microns in diameter.
SEE FIGURE 24–2.
FILTER REPLACEMENT Manufacturers recommend cleaning or replacing the air filter element at periodic intervals, usually listed in terms of distance driven or months of service. The distance and
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REMOTELY MOUNTED AIR FILTERS AND DUCTS Air cleaner and duct design depend on a number of factors such as the size, shape, and location of other engine compartment components, as well as the vehicle body structure. Port fuel-injection systems generally use a horizontally mounted throttle body. Some systems also have a mass airflow (MAF) sensor between the throttle body and the air cleaner. Because placing the air cleaner housing next to the throttle body would cause engine and vehicle design problems, it is more efficient to use this remote air cleaner placement. SEE FIGURE 24–3. Turbocharged engines present a similar problem. The air cleaner connects to the air inlet elbow at the turbocharger. However, the tremendous heat generated by the turbocharger makes it impractical to place the air cleaner housing too close to the turbocharger. Remote air cleaners are connected to the turbocharger air inlet elbow or fuel-injection throttle body by composite ducting that is usually retained by clamps. The ducting used may be rigid or flexible, but all connections must be airtight. AIR FILTER RESTRICTION INDICATOR Some vehicles, especially pickup trucks that are often driven in dusty conditions, are equipped with an air filter restriction indicator. The purpose of this device is to give a visual warning when the air filter is restricted and needs to be replaced. The device operates by detecting the slight drop in pressure that occurs when an air filter is restricted. The calibration before the red warning bar or “replace air filter” message appears varies, but is usually:
15 to 20 in. of water (in. H2O) for gasoline engines
20 to 30 in. of water (in. H2O) for diesel engines
The unit of inches of water is used to measure the difference in air pressure before and after the air filter. The unit is very small, because 28 in. of water is equal to a pound per square inch (PSI). Some air filter restriction indicators, especially on diesel engines, include an electrical switch used to light a dash-mounted warning lamp when the air filter needs to be replaced. SEE FIGURE 24–4.
(a)
FIGURE 24–4 A typical air filter restriction indicator used on a General Motors truck engine. The indicator turns red when it detects enough restriction to require a filter replacement.
TECH TIP Always Check the Air Filter Always inspect the air filter and the air intake system carefully during routine service. Debris or objects deposited by animals can cause a restriction to the airflow and can reduce engine performance. SEE FIGURE 24–5. (b)
?
FREQUENTLY ASKED QUESTION
What Does This Tube Do? What is the purpose of the odd-shape tube attached to the inlet duct between the air filter and the throttle body, as seen in FIGURE 24–6? The tube shape is designed to dampen out certain resonant frequencies that can occur at specific engine speeds. The length and shape of this tube are designed to absorb shock waves that are created in the air intake system and to provide a reservoir for the air that will then be released into the airstream during cycles of lower pressure. This resonance tube is often called a Helmholtz resonator, named for the discoverer of the relationship between shape and value of frequency, Herman L. F. von Helmholtz (1821–1894) of the University of Hönizsberg in East Prussia. The overall effect of these resonance tubes is to reduce the noise of the air entering the engine.
THROTTLE-BODY INJECTION INTAKE MANIFOLDS TERMINOLOGY The intake manifold is also called an inlet manifold. Smooth engine operation can only occur when each combustion chamber produces the same pressure as every other chamber in the engine. For this to be achieved, each cylinder must receive an
FIGURE 24–5 (a) Note the discovery as the air filter housing was opened during service on a Pontiac. The nuts were obviously deposited by squirrels (or some other animal). (b) Not only was the housing filled with nuts, but also this air filter was extremely dirty, indicating that this vehicle had not been serviced for a long time.
RESONANCE TUBE
FIGURE 24–6 A resonance tube, called a Helmholtz resonator, is used on the intake duct between the air filter and the throttle body to reduce air intake noise during engine acceleration. intake charge exactly like the charge going into the other cylinders in quality and quantity. The charges must have the same physical properties and the same air-fuel mixture. A throttle-body fuel injector forces finely divided droplets of liquid fuel into the incoming air to form a combustible air-fuel mixture. SEE FIGURE 24–7 for an example of a typical throttle-body injection (TBI) unit.
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MAXIMUM MOTORING COMPRESSION (KPA)
FIGURE 24–7 A throttle-body injection (TBI) unit used on a GM V-6 engine.
RAM-TUNING INLET TUBE LENGTH COMPARISON 2200 2000 1800
600* 450* 350* 250* 150* STD. MANIFOLD
1600 1400
* INLET RUNNER LENGTH, mm 38 mm I.D. TUBE 800 1600 2400 3200 4000 4800 5600 ENGINE SPEED (RPM)
FIGURE 24–9 The graph shows the effect of sonic tuning of the intake manifold runners. The longer runners increase the torque peak and move it to a lower RPM. The 600 mm intake runner is about 24 in. long.
PORT FUEL-INJECTION INTAKE MANIFOLDS
FIGURE 24–8 Heavy fuel droplets separate as they flow around an abrupt bend in an intake manifold.
INTAKE AIR SPEEDS
These droplets start to evaporate as soon as they leave the throttle-body injector nozzles. The droplets stay in the charge as long as the charge flows at high velocities. At maximum engine speed, these velocities may reach 300 ft per second. Separation of the droplets from the charge as it passes through the manifold occurs when the velocity drops below 50 ft per second. Intake charge velocities at idle speeds are often below this value. When separation occurs—at low engine speeds—extra fuel must be supplied to the charge in order to have a combustible mixture reach the combustion chamber. Manifold sizes and shapes represent a compromise.
They must have a cross section large enough to allow charge flow for maximum power.
The cross section must be small enough that the flow velocities of the charge will be high enough to keep the fuel droplets in suspension. This is required so that equal mixtures reach each cylinder. Manifold cross-sectional size is one reason why engines designed especially for racing will not run at low engine speeds.
Racing manifolds must be large enough to reach maximum horsepower. This size, however, allows the charge to move slowly, and the fuel will separate from the charge at low engine speeds. Fuel separation leads to poor accelerator response. SEE FIGURE 24–8.
Standard passenger vehicle engines are primarily designed for economy during light-load, partial-throttle operation. Their manifolds, therefore, have a much smaller cross-sectional area than do those of racing engines. This small size will help keep flow velocities of the charge high throughout the normal operating speed range of the engine.
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TERMINOLOGY The size and shape of port fuel-injected engine intake manifolds can be optimized because the only thing in the manifold is air. The fuel injector is located in the intake manifold about 3 to 4 in. (70 to 100 mm) from the intake valve. Therefore, the runner length and shape are designed for tuning only. There is no need to keep an air-fuel mixture thoroughly mixed (homogenized) throughout its trip from the TBI unit to the intake valve. Intake manifold runners are tuned to improve engine performance.
Long runners build low-RPM torque.
Shorter runners provide maximum high-RPM power.
SEE FIGURES 24–9 AND 24–10.
VARIABLE INTAKES Some engines with four valve heads utilize a dual or variable intake runner design. At lower engine speeds, long intake runners provide low-speed torque. At higher engine speeds, shorter intake runners are opened by means of a computercontrolled valve to increase high-speed power. Many intake manifolds are designed to provide both short runners best for higher engine speed power and longer runners best for lower engine speed torque. The valve(s) that control the flow of air through the passages of the intake manifold are computer controlled. SEE FIGURE 24–11. PLASTIC INTAKE MANIFOLDS
Most intake manifolds are made from thermoplastic molded from fiberglass-reinforced nylon by either casting or by injection molding. Some manifolds are molded in two parts and bonded together. Plastic intake manifolds are lighter than aluminum manifolds and can better insulate engine heat from the fuel injectors. Plastic intake manifolds have smoother interior surfaces than do other types of manifolds, resulting in greater airflow. SEE FIGURE 24–12.
UPPER AND LOWER INTAKE MANIFOLDS manifolds are constructed in two parts.
Many intake
IDLE AIR BYPASS VALVE THROTTLE
UPPER INTAKE MANIFOLD
PLENUM AREA FUEL PRESSURE RELIEF VALVE
AIR INTAKE
FIGURE 24–10 Airflow through the large diameter upper intake manifold is distributed to smaller diameter individual runners in the lower manifold in this two-piece manifold design.
LOWER INTAKE MANIFOLD
FUEL PRESSURE REGULATOR
FUEL RAIL
FUEL INJECTOR
A lower section attaches to the cylinder heads and includes passages from the intake ports.
An upper manifold, usually called the plenum, connects to the lower unit and includes the long passages needed to help provide the ram effect that helps the engine deliver maximum torque at low engine speeds. The throttle body attaches to the upper intake.
The use of a two-part intake manifold allows for easier manufacturing as well as assembly, but can create additional locations for leaks. If the lower intake manifold gasket leaks, not only could a vacuum leak occur affecting the operation of the engine, but a coolant leak or an oil leak can also occur if the manifold has coolant flowing through it. A leak at the gasket(s) of the upper intake manifold usually results in a vacuum (air) leak only.
FIGURE 24–11 The air flowing into the engine can be directed through long or short runners for best performance and fuel economy.
EXHAUST GAS RECIRCULATION PASSAGES PURPOSE AND FUNCTION To reduce the emission of oxides of nitrogen (NOx), engines have been equipped with exhaust gas recirculation (EGR) valves. From 1973 until recently, they were used on almost all vehicles. Most EGR valves are mounted on the intake manifold. Because of the efficiency of computer-controlled fuel injection, some newer engines do not require an EGR system to meet emission standards. These engines’ variable valve timing to close the exhaust valve sooner than normal, trapping some exhaust in the cylinder, is an alternative to using an EGR valve. On engines with EGR systems, the EGR valve opens at speeds above idle on a warm engine. When open, the valve allows a small portion of the exhaust gas (5% to 10%) to enter the intake manifold. The EGR system has some means of interconnecting of the exhaust and intake manifolds. The EGR valve controls the gas flow through the passages.
FIGURE 24–12 Many plastic intake manifolds are constructed using many parts glued together to form complex passages for airflow into the engine.
On V-type engines, the intake manifold crossover is used as a source of exhaust gas for the EGR system. A cast passage connects the exhaust crossover to the EGR valve.
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EGR VALVE
INTAKE VALVE CLOSED EXHAUST VALVE EXHAUST GASES
EXHAUST GAS TUBE
COMBUSTION CHAMBER PISTON
FIGURE 24–13 A typical long exhaust gas line used to cool the exhaust gases before being recirculated back into the intake manifold.
On inline-type engines, an external tube is generally used to carry exhaust gas to the EGR valve.
FIGURE 24–14 The exhaust gases are pushed out of the cylinder by the piston on the exhaust stroke.
EXHAUST GAS COOLERS The exhaust gases are more effective in reducing oxide of nitrogen (NOx) emissions if the exhaust is cooled before being drawn into the cylinders. This tube is often designed to be long so that the exhaust gas is cooled before it enters the EGR valve. SEE FIGURE 24–13.
EXHAUST MANIFOLDS PURPOSE AND FUNCTION The exhaust manifold is designed to collect high-temperature spent gases from the individual head exhaust ports and direct them into a single outlet connected to the exhaust system. SEE FIGURE 24–14. The hot gases are sent to an exhaust pipe, then to a catalytic converter, to the muffler, to a resonator, and on to the tailpipe, where they are vented to the atmosphere. The exhaust system is designed to meet the following needs.
Provide the least possible amount of restriction or backpressure
Keep the exhaust noise at a minimum
Exhaust gas temperature will vary according to the power produced by the engine. The manifold must be designed to operate at both engine idle and continuous full power. Under full-power conditions, the exhaust manifold can become red-hot, causing a great deal of expansion. The temperature of an exhaust manifold can exceed 1,500°F (815°C).
CONSTRUCTION
Most exhaust manifolds are made from the
following:
Cast iron
Steel tubing
During vehicle operation, manifold temperatures usually reach the high-temperature extremes. The manifold is bolted to the head in a way that will allow expansion and contraction. In some cases, hollow-headed bolts are used to maintain a gas-tight seal while still allowing normal expansion and contraction.
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FIGURE 24–15 This exhaust manifold (red area) is equipped with a heat shield to help retain heat and reduce exhaust emissions.
Many exhaust manifolds have heat shields to help keep exhaust heat off the spark plug wires and to help keep the heat from escaping to improve exhaust emissions. SEE FIGURE 24–15. Exhaust systems are especially designed for the engine-chassis combination. The exhaust system length, pipe size, and silencer are designed, where possible, to make use of the tuning effect within the exhaust system. Tuning occurs when the exhaust pulses from the cylinders are emptied into the manifold between the pulses of other cylinders. SEE FIGURE 24–16.
EXHAUST MANIFOLD GASKETS
Exhaust heat will expand the manifold more than it will expand the head. The heat causes the exhaust manifold to slide on the sealing surface of the head. The heat also causes thermal stress. When the manifold is removed from the engine for service, the stress is relieved, which may cause the manifold to warp slightly. Exhaust manifold gaskets are included in gasket sets to seal slightly warped exhaust manifolds. These gaskets should be used, even if the engine did not originally use exhaust manifold gaskets. When an exhaust manifold gasket has facing on one side only, put the facing side against the head and put the manifold against the perforated metal core. The manifold can slide on the metal of the gasket just as it slid on the sealing surface of the head.
THREADED HOLE FOR OXYGEN SENSOR
CRACK
FIGURE 24–16 Many exhaust manifolds are constructed of steel tubing and are free flowing to improve engine performance.
?
FIGURE 24–17 A crack in an exhaust manifold is often not visible because a heat shield usually covers the area. A crack in the exhaust manifold upstream of the oxygen sensor can fool the sensor and affect engine operation.
FREQUENTLY ASKED QUESTION
How Can a Cracked Exhaust Manifold Affect Engine Performance? Cracks in an exhaust manifold will not only allow exhaust gases to escape and cause noise, but also allow air to enter the exhaust manifold. SEE FIGURE 24–17. Exhaust flows from the cylinders as individual puffs or pressure pulses. Behind each of these pressure pulses, a low pressure (below atmospheric pressure) is created. Outside air at atmospheric pressure is then drawn into the exhaust manifold through the crack. This outside air contains 21% oxygen and is measured by the oxygen sensor (O2S). The air passing the O2S signals the engine computer that the engine is operating too lean (excess oxygen) and the computer, not knowing that the lean indicator is false, adds additional fuel to the engine. The result is that the engine will be operating richer (more fuel than normal) and spark plugs could become fouled by fuel, causing poor engine operation.
FIGURE 24–18 Typical exhaust manifold gaskets. Note how they are laminated to allow the exhaust manifold to expand and contract due to heating and cooling.
TECH TIP Using the Correct Tool Saves Time
Gaskets are used on new engines with tubing- or header-type exhaust manifolds. They may have several layers of steel for hightemperature sealing. The layers are spot welded together. Some are embossed where special sealing is needed. SEE FIGURE 24–18. Many new engines do not use gaskets with cast exhaust manifolds. The flat surface of the new cast-iron exhaust manifold fits tightly against the flat surface of the new head.
MUFFLERS PURPOSE AND FUNCTION
When the exhaust valve opens, it rapidly releases high-pressure gas. This sends a strong air pressure wave through the atmosphere inside the exhaust system, which produces a sound we call an explosion. It is the same sound produced when the high-pressure gases from burned gunpowder are released from a gun. In an engine, the pulses are released one after another. The explosions come so fast that they blend together in a steady roar.
When cast-iron exhaust manifolds are removed, the stresses built up in the manifolds often cause the manifolds to twist or bend. This distortion even occurs when the exhaust manifolds have been allowed to cool before removal. Attempting to reinstall distorted exhaust manifolds is often a time-consuming and frustrating exercise. However, special spreading jacks can be used to force the manifold back into position so that the fasteners can be lined up with the cylinder head. SEE FIGURE 24–19.
Sound is air vibration. When the vibrations are large, the sound is loud. The muffler catches the large bursts of high-pressure exhaust gas from the cylinder, smoothing out the pressure pulses and allowing them to be released at an even and constant rate. It does this through the use of perforated tubes within the muffler chamber. The smoothflowing gases are released to the tailpipe. In this way, the muffler silences engine exhaust noise. SEE FIGURE 24–20.
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EXHAUST MANIFOLD SPREADER TOOL
FIGURE 24–19 An exhaust manifold spreader tool is absolutely necessary when reinstalling exhaust manifolds. When they are removed from the engine, the manifolds tend to warp slightly even though the engine is allowed to cool before being removed. The spreader tool allows the technician to line up the bolt holes without harming the manifold.
FIGURE 24–21 A hole in the muffler allows condensed water to escape.
FIGURE 24–20 Exhaust gases expand and cool as they travel through passages in the muffler.
?
FREQUENTLY ASKED QUESTION
Why Is There a Hole in My Muffler? Many mufflers are equipped with a small hole in the lower rear part to drain accumulated water. About 1 gallon of water is produced in the form of steam for each gallon of gasoline burned. The water is formed when gasoline is burned in the cylinder. Water consists of two molecules of hydrogen and one of oxygen (H2O). The hydrogen (H) comes from the fuel and the oxygen (O) comes from the air. During combustion, the hydrogen from the fuel combines with some of the oxygen in the air to form water vapor. The water vapor condenses on the cooler surfaces of the exhaust system, especially in the muffler, until the vehicle has been driven long enough to fully warm the exhaust above the boiling point of water (212°F [100°C]). SEE FIGURE 24–21.
CONSTRUCTION Most mufflers have a larger inlet diameter than outlet diameter. As the exhaust enters the muffler, it expands and cools. The cooler exhaust is denser and occupies less volume. The diameter of the outlet of the muffler and the diameter of the tailpipe can be reduced with no decrease in efficiency. Sometimes resonators are used in the exhaust system and the catalytic converter also acts as a muffler. They provide additional expansion space at critical points in the exhaust system to smooth out the exhaust gas flow. The tailpipe carries the exhaust gases from the muffler to the air, away from the vehicle. In most cases, the tailpipe exit is at the rear of the vehicle, below the rear bumper. In some cases, the exhaust is released at the side of the vehicle, just ahead of or just behind the rear wheel.
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FIGURE 24–22 A high-performance aftermarket air filter often can increase airflow into the engine for more power. HIGH-PERFORMANCE TIP More Airflow ⫽ More Power One of the most popular high-performance modifications is to replace the factory exhaust system with a low-restriction design and to replace the original air filter and air filter housing with a low-restriction unit, as shown in FIGURE 24–22. The installation of an aftermarket air filter not only increases power, but also increases air induction noise, which many drivers prefer. The aftermarket filter housing, however, may not be able to effectively prevent water from being drawn into the engine if the vehicle is traveling through deep water. Almost every modification that increases performance has a negative effect on some other part of the vehicle, or else the manufacturer would include the change at the factory.
The muffler and tailpipe are supported with brackets, called hangers, which help to isolate the exhaust noise from the rest of the vehicle. The types of exhaust system hangers include:
Rubberized fabric with metal ends that hold the muffler and tailpipe in position so that they do not touch any metal part, to isolate the exhaust noise from the rest of the vehicle
Rubber material that looks like large rubber bands, which slip over the hooks on the exhaust system and the hooks attached to the body of the vehicle
REVIEW QUESTIONS 1. Why is it necessary to have intake charge velocities of about 50 ft per second?
3. What is a tuned runner in an intake manifold? 4. How does a muffler quiet exhaust noise?
2. Why can port fuel-injected engines use larger (and longer) intake manifolds and still operate at low engine speed?
CHAPTER QUIZ 1. Intake charge velocity has to be ______________ to prevent fuel droplet separation. a. 25 ft per second c. 100 ft per second b. 50 ft per second d. 300 ft per second 2. The air filter restriction indicator uses what to detect when it signals to replace the filter? a. Number of hours of engine operation b. Number of miles of vehicle travel c. The amount of light that can pass through the filter d. The amount of restriction measured in inches of water 3. Why are the EGR gases cooled before entering the engine on some engines? a. Cool exhaust gas is more effective at controlling NOx emissions b. To help prevent the exhaust from slowing down c. To prevent damage to the intake valve d. To prevent heating the air-fuel mixture in the cylinder 4. The air-fuel mixture flows through the intake manifold on what type of system? a. Port fuel-injection systems b. Throttle-body fuel-injection systems c. Both a port-injected and throttle-body injected engine d. Any fuel-injected engine 5. Air filters can remove particles and dirt as small as ______________. a. 5 to 10 microns c. 30 to 40 microns b. 10 to 25 microns d. 40 to 50 microns
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25
6. Why do many port fuel-injected engines use long intake manifold runners? a. To reduce exhaust emissions b. To heat the incoming air c. To increase high-RPM power d. To increase low-RPM torque 7. Exhaust passages are included in some intake manifolds. Technician A says that the exhaust passages are used for exhaust gas recirculation (EGR) systems. Technician B says that the upper intake is often called the plenum. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 8. The upper portion of a two-part intake manifold is often called the ______________. a. Housing c. Plenum b. Lower part d. Vacuum chamber 9. Technician A says that a cracked exhaust manifold can affect engine operation. Technician B says that a leaking lower intake manifold gasket could cause a vacuum leak. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 10. Technician A says that some intake manifolds are plastic. Technician B says that some intake manifolds are constructed in two parts or sections: upper and lower. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
TURBOCHARGING AND SUPERCHARGING
OBJECTIVES: After studying Chapter 25, the reader should be able to: • Prepare for ASE Engine Performance (A8) certification test content area “C” (Fuel, Air Induction, and Exhaust Systems Diagnosis and Repair). • Explain the difference between a turbocharger and a supercharger. • Describe how the boost levels are controlled. • Discuss maintenance procedures for turbochargers and superchargers. KEY TERMS: Boost 228 • BOV 234 • Bypass valve 230 • CBV 234 • Dry system 236 • Dump valve 234 • Forced induction systems 228 • Intercooler 233 • Naturally (normally) aspirated 228 • Nitrous oxide (N2O) 235 • Positive displacement 230 • Power adder 235 • Roots supercharger 230 • Supercharger 230 • Turbocharger 230 • Turbo lag 232 • Vent valve 234 • Volumetric efficiency 228 • Wastegate 233 • Wet system 235
T U RBO C H ARG I N G AN D SU P ERC H A RGIN G
227
SUPERCHARGER
TURBOCHARGER COVER OVER DRIVE BELT
FIGURE 25–1 A supercharger on a Ford V-8.
INTRODUCTION AIRFLOW REQUIREMENTS
Naturally aspirated engines with throttle plates use atmospheric pressure to push an air-fuel mixture into the combustion chamber vacuum created by the down stroke of a piston. The mixture is then compressed before ignition to increase the force of the burning, expanding gases. The greater the compression of the air-fuel mixture, the higher the engine power output resulting from combustion. A four-stroke engine can take in only so much air, and how much fuel it needs for proper combustion depends on how much air it takes in. Engineers calculate engine airflow requirements using three factors.
FIGURE 25–2 A turbocharger on a Toyota engine.
1. Engine displacement 2. Engine revolutions per minute (RPM) 3. Volumetric efficiency
VOLUMETRIC EFFICIENCY Volumetric efficiency is a measure of how well an engine breathes. It is a comparison of the actual volume of air-fuel mixture drawn into an engine to the theoretical maximum volume that could be drawn in. Volumetric efficiency is expressed as a percentage. If the engine takes in the airflow volume slowly, a cylinder might fill to capacity. It takes a definite amount of time for the airflow to pass through all the curves of the intake manifold and valve port. Therefore, volumetric efficiency decreases as engine speed increases due to the shorter amount of time for the cylinders to be filled with air during the intake stroke. At high speed, it may drop to as low as 50%. The average stock gasoline engine never reaches 100% volumetric efficiency. A new engine is about 85% efficient. A race engine usually has 95% or better volumetric efficiency. These figures apply only to naturally aspirated engines. However, with either turbochargers or superchargers, engines can easily achieve more than 100% volumetric efficiency. Many vehicles are equipped with a supercharger or a turbocharger from the factory to increase power. SEE FIGURES 25–1 AND 25–2.
FORCED INDUCTION PRINCIPLES
LOW DENSITY
HIGH DENSITY
FIGURE 25–3 The more air and fuel that can be packed in a cylinder, the greater the density of the air-fuel charge. the amount of the air-fuel charge introduced into the cylinders. Density is the mass of a substance in a given amount of space. SEE FIGURE 25–3. The greater the density of an air-fuel charge forced into a cylinder, the greater the force it produces when ignited, and the greater the engine power. An engine that uses atmospheric pressure for its intake charge is called a naturally (normally) aspirated engine. A better way to increase air density is to use some type of air pump such as a turbocharger or supercharger. When air is pumped into the cylinder, the combustion chamber receives an increase of air pressure known as boost, and can be measured in:
Pounds per square inch (PSI)
Atmospheres (ATM) (1 atmosphere is 14.7 PSI)
Bars (1 bar is 14.7 PSI)
While boost pressure increases air density, friction heats air in motion and causes an increase in temperature. This increase in temperature works in the opposite direction, decreasing air density. Because of these and other variables, an increase in pressure does not always result in greater air density.
PURPOSE AND FUNCTION
The amount of force an airfuel charge produces when it is ignited is largely a function of the charge density. Charge density is a term used to define
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FORCED INDUCTION PRINCIPLES
Forced induction systems use an air pump to pack a denser air-fuel charge into the
PIKES PEAK (14,000 FT.) 8.6 PSI
DENVER (5000 FT.) 13.0 PSI
ST. LOUIS (600 FT.) 14.4 PSI
NEW YORK CITY 14.7 PSI
FIGURE 25–4 Atmospheric pressure decreases with increases in altitude.
FINAL COMPRESSION RATIO CHART AT VARIOUS BOOST LEVELS BLOWER BOOST (PSI) 2
4
6
10
12
14
16
18
20
6.5
7.4
8.3
9.2
10
10.9
11.8
12.7
13.6
14.5
15.3
7
8
8.9
9.9
10.8
11.8
12.7
13.6
14.5
15.3
16.2
7.5
8.5
9.5
10.6
11.6
12.6
13.6
14.6
15.7
16.7
17.8
8
9.1
10.2
11.3
12.4
13.4
14.5
15.6
16.7
17.8
18.9
COMP RATIO
8
9.7
10.8
12
13.1
14.3
15.4
16.6
17.8
18.9
19.8
9
10.2
11.4
12.7
13.9
15.1
16.3
17.6
18.8
20
21.2
9.5
10.8
12.1
13.4
14.7
16
17.3
18.5
19.8
21.1
22.4
11.4
12.7
14.1
15.4
16.8
18.2
19.5
20.9
22.2
23.6
8.5
10 CHART 25–1
The effective compression ratio compared to the boost pressure. cylinders. Because the density of the air-fuel charge is greater, the following occurs.
The weight of the air-fuel charge is higher.
Power is increased because it is directly related to the weight of an air-fuel charge consumed within a given time period.
Pumping air into the intake system under pressure forces it through the bends and restrictions of the air intake system at a greater speed than it would travel under normal atmospheric pressure. This added pressure allows more air to enter the intake port before the intake valve closes. By increasing the airflow into the intake, more fuel can be mixed with the air while still maintaining the same air-fuel ratio. The denser the air-fuel charge entering the engine during its intake stroke, the greater the potential energy released during combustion. In addition to the increased power resulting from combustion, there are several other advantages of supercharging an engine, including:
It increases the air-fuel charge density to provide highcompression pressure when power is required, but allows the engine to run on lower pressures when additional power is not required. The pumped air pushes the remaining exhaust from the combustion chamber during intake and exhaust valve overlap. (Overlap is when both the intake and exhaust valves are partially open when the piston is near the top at the end of the exhaust stroke and the beginning of the intake stroke.)
The forced airflow and removal of hot exhaust gases lowers the temperature of the cylinder head, pistons, and valves, and helps extend the life of the engine.
A supercharger or turbocharger pressurizes air to greater than atmospheric pressure. The pressurization above atmospheric pressure, or boost, can be measured in the same way as atmospheric pressure. Atmospheric pressure drops as altitude increases, but boost pressure remains the same. If a supercharger develops 12 PSI (83 kPa) boost at sea level, it will develop the same amount at a 5,000 ft altitude because boost pressure is measured inside the intake manifold. SEE FIGURE 25–4.
BOOST AND COMPRESSION RATIOS Boost increases the amount of air drawn into the cylinder during the intake stroke. This extra air causes the effective compression ratio to be greater than the mechanical compression ratio designed into the engine. The higher the boost pressure, the greater the compression ratio. This means that any engine that uses a supercharger or turbocharger must use all of the following engine components.
Forged pistons, to withstand the increased combustion pressures
Stronger than normal connecting rods
Piston oil squirters that direct a stream of oil to the underneath part of the piston, to keep piston temperatures under control
Lower compression ratio compared to a naturally aspirated engine
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A centrifugal supercharger is not a positive displacement pump and all of the air that enters is not forced through the unit. Air enters a centrifugal supercharger housing in the center and exits at the outer edges of the compressor wheels at a much higher speed due to centrifugal force. The speed of the blades has to be higher than engine speed so a smaller pulley is used on the supercharger and the crankshaft overdrives the impeller through an internal gear box achieving about seven times the speed of the engine. Examples of centrifugal superchargers include Vortech and Paxton.
SUPERCHARGERS INTRODUCTION A supercharger is an engine-driven air pump that supplies more than the normal amount of air into the intake manifold and boosts engine torque and power. A supercharger provides an instantaneous increase in power without any delay. However, a supercharger, because it is driven by the engine, requires horsepower to operate and is not as efficient as a turbocharger. A supercharger is an air pump mechanically driven by the engine itself. Gears, shafts, chains, or belts from the crankshaft can all be used to turn the pump. This means that the air pump or supercharger pumps air in direct relation to engine speed. TYPES OF SUPERCHARGERS
There are two general types
of superchargers.
Roots type. Named for Philander and Francis Roots, two brothers from Connersville, Indiana, the roots supercharger was patented in 1860 as a type of water pump to be used in mines. Later, it was used to move air and is used today on two-stroke-cycle Detroit diesel engines and other supercharged engines. The roots-type supercharger is called a positive displacement design, because all of the air that enters is forced through the unit. Examples of a roots-type supercharger include the GMC 6-71 (used originally on GMC diesel engines that had 6 cylinders each with 71 cu. in.). Eaton used the roots design for the supercharger on the 3800 V-6 GM engine. SEE FIGURE 25–5. Centrifugal supercharger. A centrifugal supercharger is similar to a turbocharger, but is mechanically driven by the engine instead of being powered by the hot exhaust gases.
SUPERCHARGER BOOST CONTROL
Many factory installed superchargers are equipped with a bypass valve that allows intake air to flow directly into the intake manifold, bypassing the supercharger. The computer controls the bypass valve actuator. SEE FIGURE 25–6. The airflow is directed around the supercharger whenever any of the following conditions occur.
The boost pressure, as measured by the MAP sensor, indicates that the intake manifold pressure is reaching the predetermined boost level.
During deceleration, to prevent excessive pressure buildup in the intake.
Reverse gear is selected.
SUPERCHARGER SERVICE Superchargers are usually lubricated with synthetic engine oil inside the unit. This oil level should be checked and replaced as specified by the vehicle or supercharger manufacturer. The drive belt should also be inspected and replaced as necessary. The air filter should be replaced regularly, and always use the filter specified for a supercharged engine. Many factory supercharger systems use a separate cooling system for the air charge cooler located under the supercharger. Check service information for the exact service procedures to follow. SEE FIGURE 25–7.
TURBOCHARGERS LOBE
FIGURE 25–5 A roots-type supercharger uses two lobes to force the air around the outside of the housing and into the intake manifold.
INTRODUCTION The major disadvantage of a supercharger is it takes some of the engine power to drive the unit. In some installations, as much as 20% of the engine power is used by a mechanical supercharger. A turbocharger uses the heat of the exhaust to power
BYPASS ACTUATOR DRIVE PULLEY
TO VACUUM SOURCE (CONTROLLED BY THE COMPUTER)
SUPERCHARGER THROTTLE BODY
LOWER INTAKE PLEUM
BYPASS VALVE
FIGURE 25–6 The bypass actuator opens the bypass valve to control boost pressure.
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FUEL IN 100%
ROOTS-TYPE BLOWER
RADIATOR COOLING 25%
POWER OUT 25%
EXHAUST OUT 50%
FIGURE 25–8 A turbocharger uses some of the heat energy that would normally be wasted. EXHAUST
TURBINE WHEEL AIR CHARGE COOLER
FIGURE 25–7 A Ford supercharger cutaway display showing the roots-type blower and air charge cooler (intercooler). The air charge cooler is used to reduce the temperature of the compressed air before it enters the engine to increase the air charge density.
IMPELLER (COMPRESSOR) EXHAUST
TECH TIP Faster Moves More Air One of the high-performance measures that can be used to increase horsepower on a supercharged engine is to install a smaller diameter pulley. The smaller the pulley diameter, the faster the supercharger will rotate and the higher the potential boost pressure will be. The change will require a shorter belt, and the extra boost could cause serious engine damage.
a turbine wheel and therefore does not directly reduce engine power. In a naturally aspirated engine, about half of the heat energy contained in the fuel goes out the exhaust system. However, some engine power is lost due to the exhaust restriction. This loss in power is regained, though, to perform other work and the combustion heat energy lost in the engine exhaust (as much as 40% to 50%) can be harnessed to do useful work. Another 25% is lost through radiator cooling. Only about 25% is actually converted to mechanical power. A mechanically driven pump uses some of this mechanical output, but a turbocharger gets its energy from the exhaust gases, converting more of the fuel’s heat energy into useful mechanical energy. SEE FIGURE 25–8.
OPERATION A turbocharger turbine looks much like a typical centrifugal pump used for supercharging. Hot exhaust gases flow from the combustion chamber to the turbine wheel. The gases are heated and expanded as they leave the engine. It is not the speed of force of the exhaust gases that forces the turbine wheel to turn, as is commonly thought, but the expansion of hot gases against the turbine wheel’s blades. A turbocharger consists of two chambers connected with a center housing. The two chambers contain a turbine wheel and an impeller (compressor) wheel connected by a shaft which passes through the center housing. SEE FIGURE 25–9
FIGURE 25–9 A turbine wheel is turned by the expanding exhaust gases.
IMPELLER (COMPRESSOR)
TURBINE WHEEL
FIGURE 25–10 The exhaust drives the turbine wheel on the left which is connected to the impeller wheel on the right through a shaft. The bushings that support the shaft are lubricated with engine oil under pressure. To take full advantage of the exhaust heat which provides the rotating force, a turbocharger must be positioned as close as possible to the exhaust manifold. This allows the hot exhaust to pass directly into the unit with minimal heat loss. As exhaust gas enters the turbocharger, it rotates the turbine blades. The turbine wheel and compressor wheel are on the same shaft so that they turn at the same speed. Rotation of the compressor wheel draws air in through a central inlet and centrifugal force pumps it through an outlet at the edge of the housing. A pair of bearings in the center housing supports the turbine and compressor wheel shaft, and is lubricated by engine oil. SEE FIGURE 25–10.
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OIL LINE TO TURBOCHARGER BUSHINGS
TURBINE (EXHAUST SIDE)
IMPELLER (AIR SIDE)
FIGURE 25–11 Engine oil is fed to the center of the turbocharger to lubricate the bushings and returns to the oil pan through a return line.
Both the turbine and compressor wheels must operate with extremely close clearances to minimize possible leakage around their blades. Any leakage around the turbine blades causes a dissipation of the heat energy required for compressor rotation. Leakage around the compressor blades prevents the turbocharger from developing its full boost pressure.
TURBOCHARGER OPERATION When the engine is started and runs at low speed, both exhaust heat and pressure are low and the turbine runs at a low speed (approximately 1000 RPM). Because the compressor does not turn fast enough to develop boost pressure, air simply passes through it and the engine works like any naturally aspirated engine. As the engine runs faster or load increases, both exhaust heat and flow increase, causing the turbine and compressor wheels to rotate faster. Since there is no brake and very little rotating resistance on the turbocharger shaft, the turbine and compressor wheels accelerate as the exhaust heat energy increases. When an engine is running at full power, the typical turbocharger rotates at speeds between 100,000 and 150,000 RPM. The turbocharger is lubricated by engine oil through an oil line to the center bearing assembly. SEE FIGURE 25–11. Engine deceleration from full power to idle requires only a second or two because of its internal friction, pumping resistance, and drivetrain load. The turbocharger, however, has no such load on its shaft, and is already turning many times faster than the engine at top speed. As a result, it can take as much as a minute or more after the engine has returned to idle speed before the turbocharger also has returned to idle. If the engine is decelerated to idle and then shut off immediately, engine lubrication stops flowing to the center housing bearings while the turbocharger is still spinning at thousands of RPM. The oil in the center housing is then subjected to extreme heat and can gradually “coke” or oxidize. The coked oil can clog passages and will reduce the life of the turbocharger. The high rotating speeds and extremely close clearances of the turbine and compressor wheels in their housings require equally critical bearing clearances. The bearings must keep radial clearances of 0.003 to 0.006 in. (0.08 to 0.15 mm). Axial clearance (endplay) must be maintained at 0.001 to 0.003 in. (0.025 to 0.08 mm). If properly maintained, the turbocharger also is a trouble-free device. However, to prevent problems, the following must be met.
The turbocharger bearings must be constantly lubricated with clean engine oil. Turbocharged engines usually have specified
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oil changes at more frequent intervals than nonturbocharged engines. Always use the specified engine oil, which is likely to be vehicle specific and synthetic.
Dirt particles and other contamination must be kept out of the intake and exhaust housings.
Whenever a basic engine bearing (crankshaft or camshaft) has been damaged, the turbocharger must be flushed with clean engine oil after the bearing has been replaced.
If the turbocharger is damaged, the engine oil must be drained and flushed and the oil filter replaced as part of the repair procedure.
Late-model turbochargers all have liquid-cooled center bearings to prevent heat damage. In a liquid-cooled turbocharger, engine coolant is circulated through passages cast in the center housing to draw off the excess heat. This allows the bearings to run cooler and minimize the probability of oil coking when the engine is shut down.
TURBOCHARGER SIZE AND RESPONSE TIME A time lag occurs between an increase in engine speed and the increase in the speed of the turbocharger. This delay between acceleration and turbo boost is called turbo lag. Like any material, moving exhaust gas has inertia. Inertia also is present in the turbine and compressor wheels, as well as the intake airflow. Unlike a supercharger, the turbocharger cannot supply an adequate amount of boost at low speed. Turbocharger response time is directly related to the size of the turbine and compressor wheels. Small wheels accelerate rapidly; large wheels accelerate slowly. While small wheels would seem to have an advantage over larger ones, they may not have enough airflow capacity for an engine. To minimize turbo lag, the intake and exhaust breathing capacities of an engine must be matched to the exhaust and intake airflow capabilities of the turbocharger.
BOOST CONTROL PURPOSE AND FUNCTION Both supercharged and turbocharged systems are designed to provide a pressure greater than atmospheric pressure in the intake manifold. This increased pressure forces additional amounts of air into the combustion chamber over what would normally be forced in by atmospheric pressure. This increased charge increases engine power. The amount of “boost” (or pressure in the intake manifold) is measured in pounds per square inch (PSI), in inches of mercury (in. Hg), in bars, or in atmospheres. The following values will vary due to altitude and weather conditions (barometric pressure). 1 atmosphere ⫽ 14.7 PSI 1 atmosphere ⫽ 29.50 in. Hg 1 atmosphere ⫽ 1 bar 1 bar ⫽ 14.7 PSI
BOOST CONTROL FACTORS
The higher the level of boost (pressure), the greater the horsepower output potential. However, other factors must be considered when increasing boost pressure. 1. As boost pressure increases, the temperature of the air also increases. 2. As the temperature of the air increases, combustion temperatures also increase, as well as the possibility of detonation. 3. Power can be increased by cooling the compressed air after it leaves the turbocharger. The power can be increased about
1% per 10°F by which the air is cooled. A typical cooling device is called an intercooler. It is similar to a radiator, wherein outside air can pass through, cooling the pressurized heated air. An intercooler is located between the turbocharger and the intake manifold. SEE FIGURE 25–12. Some intercoolers use engine coolant to cool the hot compressed air that flows from the turbocharger to the intake.
4. As boost pressure increases, combustion temperature and pressures increase, which, if not limited, can do severe engine damage. The maximum exhaust gas temperature must be 1,550°F (840°C). Higher temperatures decrease the durability of the turbocharger and the engine.
WASTEGATE Turbochargers use exhaust gases to increase boost, which causes the engine to make more exhaust gases, which in turn increases the boost from the turbocharger. To prevent overboost and severe engine damage, most turbocharger systems use a wastegate. A wastegate is a valve similar to a door that can open and close. It is a bypass valve at the exhaust inlet to the turbine, which allows all of the exhaust into the turbine, or it can route part of the exhaust past the turbine to the exhaust system. If the valve is closed, all of the exhaust travels to the turbocharger. When a predetermined amount of boost pressure develops in the intake manifold, the wastegate valve is opened. As the valve opens, most of the exhaust flows directly out the exhaust system, bypassing the turbocharger. With less exhaust flowing across the vanes of the turbocharger, the turbocharger decreases in speed, and boost pressure is reduced. When the boost pressure drops, the wastegate valve closes to direct the exhaust over the turbocharger vanes to again allow the boost pressure to rise. Wastegate operation is a continuous process to control boost pressure. The wastegate is the pressure control valve of a turbocharger system. It is usually controlled by the engine control computer through a boost control solenoid, also called a wastegate control valve. SEE FIGURE 25–13.
FIGURE 25–12 The unit on top of this Subaru that looks like a radiator is the intercooler, which cools the air after it has been compressed by the turbocharger.
WASTEGATE CONTROL VALVE (N.C.) VENT TO AIR CLEANER
PCM IGN.
BOOST PRESSURE
WASTEGATE (OPEN)
INTAKE EXHAUST STROKE
COMPRESSOR
TURBINE
EXHAUST
FIGURE 25–13 A wastegate is used on many turbocharged engines to control maximum boost pressure. The wastegate is controlled by a computer-controlled valve.
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RELIEF VALVES A wastegate controls the exhaust side of the turbocharger. A relief valve controls the intake side. A relief valve vents pressurized air from the connecting pipe between the outlet of the turbocharger and the throttle whenever the throttle is closed during boost, such as during shifts. If the pressure is not released, the turbocharger turbine wheel will slow down, creating a lag when the throttle is opened again after a shift has been completed. There are two basic types of relief valves. 1. Compressor bypass valve (CBV). This type of relief valve routes the pressurized air to the inlet side of the turbocharger for reuse and is quiet during operation. 2. Blow-off valve (BOV). Also called a dump valve or vent valve, the BOV features an adjustable spring design that keeps the
TECH TIP Boost Is the Result of Restriction The boost pressure of a turbocharger (or supercharger) is commonly measured in pounds per square inch. If a cylinder head is restricted because of small valves and ports, the turbocharger will quickly provide boost. Boost results when the air being forced into the cylinder heads cannot flow into the cylinders fast enough and “piles up” in the intake manifold, increasing boost pressure. If an engine had large valves and ports, the turbocharger could provide a much greater amount of air into the engine at the same boost pressure as an identical engine with smaller valves and ports. Therefore, by increasing the size of the valves, a turbocharged or supercharged engine will be capable of producing much greater power.
valve closed until a sudden release of the throttle. The resulting pressure increase opens the valve and vents the pressurized air directly into the atmosphere. This type of relief valve is noisy in operation and creates a whooshing sound when the valve opens. SEE FIGURE 25–14.
TURBOCHARGER FAILURES SYMPTOMS OF FAILURE
When turbochargers fail to function correctly, a noticeable drop in power occurs. To restore proper operation, the turbocharger must be rebuilt, repaired, or replaced. It is not possible to simply remove the turbocharger, seal any openings, and maintain decent driveability. Bearing failure is a common cause of turbocharger failure, and replacement bearings are usually only available to rebuilders. Another common turbocharger problem is excessive and continuous oil consumption resulting in blue
TECH TIP If One Is Good, Two Are Better A turbocharger uses the exhaust from the engine to spin a turbine, which is connected to an impeller inside a turbocharger. This impeller then forces air into the engine under pressure, higher than is normally achieved without a turbocharger. The more air that can be forced into an engine, the greater the power potential. A V-type engine has two exhaust manifolds and so two small turbochargers can be used to help force greater quantities of air into an engine, as shown in FIGURE 25–15.
SPRING
RELIEF VALVE THROTTLE VALVE (CLOSED)
BLOWOFF VALVE BOOST PRESSURE
WASTEGATE (CLOSED)
INTAKE EXHAUST STROKE
COMPRESSOR
TURBINE
EXHAUST
FIGURE 25–14 A blow-off valve is used in some turbocharged systems to relieve boost pressure during deceleration.
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FIGURE 25–15 A dual turbocharger system installed on a small block Chevrolet V-8 engine. exhaust smoke. Turbochargers use small rings similar to piston rings on the shaft to prevent exhaust (combustion gases) from entering the central bearing. Because there are no seals to keep oil in, excessive oil consumption is usually caused by the following: 1. Plugged positive crankcase ventilation (PCV) system, resulting in excessive crankcase pressures forcing oil into the air inlet (This failure is not related to the turbocharger, but the turbocharger is often blamed.) 2. Clogged air filter, which causes a low-pressure area in the inlet, drawing oil past the turbo shaft rings and into the intake manifold. 3. Clogged oil return (drain) line from the turbocharger to the oil pan (sump), which can cause the engine oil pressure to force oil past the turbocharger’s shaft rings and into the intake and exhaust manifolds (Obviously, oil being forced into both the intake and exhaust would create lots of smoke.)
PREVENTING TURBOCHARGER FAILURES
To help prevent turbocharger failures, the wise vehicle owner should follow the vehicle manufacturer’s recommended routine service procedures. The most critical of these services include:
Regular oil changes (synthetic oil would be best)
Regular air filter replacement intervals
Performing any other inspections and services recommended such as cleaning the intercooler.
NITROUS OXIDE INTRODUCTION Nitrous oxide is used for racing or highperformance only, and is not used from the factory on any vehicle. This system is a relatively inexpensive way to get additional power from an engine, but can cause serious engine damage if not used correctly or in excess amounts, or without proper precautions. PRINCIPLES Nitrous oxide (N2O) is a colorless, nonflammable gas. It was discovered by a British chemist, Joseph Priestly (1733–1804), who also discovered oxygen. Priestly found that if a person breathed in nitrous oxide, it caused light-headedness, and so the gas soon became known as laughing gas. Nitrous oxide
TEMPERATURE (°F/°C)
PRESSURE (PSI/KPA)
⫺30°F/⫺34°C
67 PSI/468 kPa
⫺20°F/⫺29°C
203 PSI/1,400 kPa
⫺10°F/⫺23°C
240 PSI/1,655 kPa
0°F/⫺18°C
283 PSI/1,950 kPa
10°F/⫺12°C
335 PSI/2,310 kPa
20°F/⫺7°C
387 PSI/2,668 kPa
30°F/⫺1°C
460 PSI/3,172 kPa
40°F/4°C
520 PSI/3,585 kPa
50°F/10°C
590 PSI/4,068 kPa
60°F/16°C
675 PSI/4,654 kPa
70°F/21°C
760 PSI/5,240 kPa
80°F/27°C
865 PSI/5,964 kPa
90°F/32°C
985 PSI/6,792 kPa
100°F/38°C
1,120 PSI/7,722 kPa
CHART 25–2 Temperature/pressure relation for nitrous oxide: The higher the temperature, the higher the pressure.
was used in dentistry during tooth extractions to reduce the pain and cause the patient to forget the experience. Nitrous oxide has two nitrogen atoms and one oxide atom. About 36% of the molecule weight is oxygen. Nitrous oxide is a manufactured gas because, even though both nitrogen and oxygen are present in our atmosphere, they are not combined into one molecule and require heat and a catalyst to be combined.
ENGINE POWER ADDER
A power adder is a device or system added to an engine, such as a supercharger, turbocharger, or nitrous oxide, to increase power. When nitrous oxide is injected into an engine along with gasoline, engine power is increased. The addition of N2O supplies the needed oxygen for the extra fuel. N2O by itself does not burn, but provides the oxygen for additional fuel that is supplied along with the N2O to produce more power. NOTE: Nitrous oxide was used as a power adder in World War II on some fighter aircraft. Having several hundred more horsepower for a short time saved many lives.
PRESSURE AND TEMPERATURE It requires about 11 lb of pressure per degree Fahrenheit to condense nitrous oxide gas into liquid nitrous oxide. For example, at 70°F, it requires a pressure of about 770 PSI to condense N2O into a liquid. To change N2O from a liquid under pressure to a gas, all that is needed is to lower its pressure below the pressure it takes to cause it to become a liquid. The temperature also affects the pressure of N2O. SEE CHART 25–2. Nitrous oxide is stored in a pressurized storage container and installed at an angle so the pickup tube is in the liquid. The front or discharge end of the storage bottle should be toward the front of the vehicle. SEE FIGURE 25–16. WET AND DRY SYSTEM There are two different types of N2O systems that depend on whether additional fuel (gasoline) is supplied at the same time as when the nitrous oxide is squirted.
The wet system involves additional fuel being injected. It is identified as having both a red and a blue nozzle, with the red flowing gasoline and the blue flowing nitrous oxide.
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THIS SIDE UP
FRONT OF VEHICLE
LIQUID N2O
FIGURE 25–16 Nitrous bottles have to be mounted at an angle to ensure that the pickup tube is in the liquid N2O.
In a dry system, such as an engine using port fuel injection, only nitrous oxide needs to be injected because the PCM can be commanded to provide more fuel when the N2O is being sprayed. As a result, the intake manifold contains only air and the injected gaseous N2O.
FIGURE 25–17 An electrical heating mat is installed on the bottle of nitrous oxide to increase the pressure of the gas inside. TECH TIP
ENGINE CHANGES NEEDED FOR N2O
If nitrous oxide is going to be used to increase horsepower more than 50 hp, the engine must be designed and built to withstand the greater heat and pressure that will occur in the combustion chambers. For example, the following items should be considered if adding a turbocharger, supercharger, or nitrous oxide system.
Forged pistons are best able to withstand the pressure and temperature when using nitrous oxide or other power adder.
Cylinder-to-wall clearance should be increased. Due to the greater amount of heat created by the extra fuel and N2O injection, the piston temperature will be increased. Although using forged pistons will help, most experts recommend using increased cylinder-to-wall clearance.
Using forged crankshaft and connecting rods.
Check the instructions from the nitrous oxide supplier for details and other suggested changes. CAUTION: The use of a nitrous oxide injection system can cause catastrophic engine damage. Always follow the instructions that come with the kit and be sure that all of the internal engine parts meet the standard specified to help avoid severe engine damage.
Increase Bottle Pressure To increase the pressure of the nitrous oxide in a bottle, an electrical warming blanket can be used, as seen in FIGURE 25–17. The higher the temperature, the higher the pressure and the greater the amount of N2O flow when energized.
SYSTEM INSTALLATION AND CALIBRATION
Nitrous oxide systems are usually purchased as a kit with all of the needed components included. The kit also includes one or more sizes of nozzle(s), which are calibrated to control the flow of nitrous oxide into the intake manifold. The sizes of the nozzles are often calibrated in horsepower that can be gained by their use. Commonly sized nozzles include:
50 hp
100 hp
150 hp
Installation of a nitrous oxide kit also includes the installation of an on-off switch and a switch on or near the throttle, which is used to activate the system only when the throttle is fully opened (WOT).
REVIEW QUESTIONS 1. What are the reasons why supercharging increases engine power? 2. How does the bypass valve work on a supercharged engine?
4. What are the advantages and disadvantages of turbocharging? 5. What turbocharger control valves are needed for proper engine operation?
3. What are the advantages and disadvantages of supercharging?
CHAPTER QUIZ 1. Boost pressure is generally measured in ______________. a. in. Hg c. in. H2O b. PSI d. in. lb
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2. Two types of superchargers include ______________. a. Rotary and reciprocating c. Double and single acting b. Roots-type and centrifugal d. Turbine and piston
3. Which valve is used on a factory supercharger to limit boost? a. Bypass valve c. Blow-off valve b. Wastegate d. Air valve 4. How are most superchargers lubricated? a. By engine oil under pressure through lines from the engine b. By an internal oil reservoir c. By greased bearings d. No lubrication is needed because the incoming air cools the supercharger
7. What is the purpose of an intercooler? a. To reduce the temperature of the air entering the engine b. To cool the turbocharger c. To cool the engine oil on a turbocharged engine d. To cool the exhaust before it enters the turbocharger 8. Which type of relief valve used on a turbocharged engine is noisy? a. Bypass valve c. Dump valve b. BOV d. Both b and c
5. How are most turbochargers lubricated? a. By engine oil under pressure through lines from the engine b. By an internal oil reservoir c. By greased bearings d. No lubrication is needed because the incoming air cools the supercharger
9. Technician A says that a stuck open wastegate can cause the engine to burn oil. Technician B says that a clogged PCV system can cause the engine to burn oil. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
6. Two technicians are discussing the term turbo lag. Technician A says that it refers to the delay between when the exhaust leaves the cylinder and when it contacts the turbine blades of the turbocharger. Technician B says that it refers to the delay in boost pressure that occurs when the throttle is first opened. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
10. What service operation is most important on engines equipped with a turbocharger? a. Replacing the air filter regularly b. Replacing the fuel filter regularly c. Regular oil changes d. Regular exhaust system maintenance
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26
ENGINE CONDITION DIAGNOSIS
OBJECTIVES: After studying Chapter 26, the reader should be able to: • Prepare for ASE Engine Performance (A8) certification test content area “A” (General Engine Diagnosis). • List the visual checks to determine engine condition. • Discuss engine noise and its relation to engine condition. • Describe how to perform a dry and a wet compression test. • Explain how to perform a cylinder leakage test. KEY TERMS: Back pressure 248 • Compression test 242 • Cranking vacuum test 246 • Cylinder leakage test 244 • Dynamic compression test 244 • Idle vacuum test 246 • Inches of mercury (in. Hg) 245 • Paper test 242 • Power balance test 245 • Restricted exhaust 247 • Running compression test 244 • Vacuum test 246 • Wet compression test 243
If there is an engine operation problem, then the cause could be any one of many items, including the engine itself. The condition of the engine should be tested anytime the operation of the engine is not satisfactory.
TYPICAL ENGINE-RELATED COMPLAINTS Many driveability problems are not caused by engine mechanical problems. A thorough inspection and testing of the ignition and fuel systems should be performed before testing for mechanical engine problems.
Typical engine mechanical-related complaints include the following:
Excessive oil consumption
Engine misfiring
Loss of power
Smoke from the engine or exhaust
Engine noise
ENGINE SMOKE DIAGNOSIS The color of engine exhaust smoke can indicate what engine problem might exist.
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CRANKCASE VENT HOSE
FIGURE 26–1 Blowby gases coming out of the crankcase vent hose. Excessive amounts of combustion gases flow past the piston rings and into the crankcase.
FIGURE 26–2 White steam is usually an indication of a blown (defective) cylinder head gasket that allows engine coolant to flow into the combustion chamber where it is turned to steam.
Typical Exhaust Smoke Color
Possible Causes
Blue
Blue exhaust indicates that the engine is burning oil. Oil is getting into the combustion chamber either past the piston rings or past the valve stem seals. Blue smoke only after start-up is usually due to defective valve stem seals. SEE FIGURE 26–1.
Black
Black exhaust smoke is due to excessive fuel being burned in the combustion chamber. Typical causes include a defective or misadjusted throttle body, leaking fuel injector, or excessive fuelpump pressure.
White (steam)
White smoke or steam from the exhaust is normal during cold weather and represents condensed steam. Every engine creates about 1 gallon of water for each gallon of gasoline burned. If the steam from the exhaust is excessive, then water (coolant) is getting into the combustion chamber. Typical causes include a defective cylinder head gasket, a cracked cylinder head, or in severe cases a cracked block. SEE FIGURE 26–2.
Note: White smoke can also be created when automatic transmission fluid (ATF) is burned. A common source of ATF getting into the engine is through a defective vacuum modulator valve on older automatic transmissions.
OIL LEVEL AND CONDITION
THE DRIVER IS YOUR BEST RESOURCE The driver of the vehicle knows a lot about the vehicle and how it is driven. Before diagnosis is started, always ask the following questions.
When did the problem first occur? Under what conditions does it occur? 1. Cold or hot? 2. Acceleration, cruise, or deceleration? 3. How far was it driven? 4. What recent repairs have been performed?
After the nature and scope of the problem are determined, the complaint should be verified before further diagnostic tests are performed.
VISUAL CHECKS The first and most important “test” that can be performed is a careful visual inspection.
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The first area for visual inspec-
tion is oil level and condition. 1. Oil level—oil should be to the proper level 2. Oil condition a. Using a match or lighter, try to light the oil on the dipstick; if the oil flames up, gasoline is present in the engine oil. b. Drip some of the engine oil from the dipstick onto the hot exhaust manifold. If the oil bubbles or boils, there is coolant (water) in the oil. c. Check for grittiness by rubbing the oil between your fingers.
COOLANT LEVEL AND CONDITION Most mechanical engine problems are caused by overheating. The proper operation of the cooling system is critical to the life of any engine. NOTE: Check the coolant level in the radiator only if the radiator is cool. If the radiator is hot and the radiator cap is removed, the drop in pressure above the coolant will cause the coolant to boil immediately and can cause severe burns when the coolant explosively expands upward and outward from the radiator opening. 1. The coolant level in the coolant recovery container should be within the limits indicated on the overflow bottle. If this level is too low or the coolant recovery container is empty, then check the level of coolant in the radiator (only when cool) and also check the operation of the pressure cap.
HARMONIC BALANCER
OIL PAN
FIGURE 26–3 What looks like an oil pan gasket leak can be a rocker cover gasket leak. Always look up and look for the highest place you see oil leaking; that should be repaired first.
TECH TIP Your Nose Knows Whenever diagnosing any vehicle try to use all senses including smell. Some smells and their cause include: • Gasoline. If the exhaust smells like gasoline or unburned fuel, then a fault with the ignition system is a likely cause. Unburned fuel due to lean air-fuel mixture causing a lean misfire is also possible. • Sweet smell. A coolant leak often gives off a sweet smell especially if the leaking coolant flows onto the hot exhaust. • Exhaust smell. Check for an exhaust leak including a possible cracked exhaust manifold which can be difficult to find because it often does not make noise.
2. The coolant should be checked with a hydrometer for boiling and freezing temperature. This test indicates if the concentration of the antifreeze is sufficient for proper protection. 3. Pressure test the cooling system and look for leakage. Coolant leakage can often be seen around hoses or cooling system components because it will often cause: a. A grayish white stain b. A rusty color stain c. Dye stains from antifreeze (greenish or yellowish depending on the type of coolant)
FIGURE 26–4 The transmission and flexplate (flywheel) were removed to check the exact location of this oil leak. The rear main seal and/or the oil pan gasket could be the cause of this leak.
TECH TIP What’s Leaking? The color of the leaks observed under a vehicle can help the technician determine and correct the cause. Some leaks, such as condensate (water) from the air-conditioning system, are normal, whereas a brake fluid leak is very dangerous. The following are colors of common leaks. Sooty Black
Engine Oil
Yellow, green, blue, or orange Red Murky brown
Antifreeze (coolant)
Clear
Automatic transmission fluid Brake or power steering fluid or very neglected antifreeze (coolant) Air-conditioning condensate (water) (normal)
4. Check for cool areas of the radiator indicating clogged sections. 5. Check operation and condition of the fan clutch, fan, and coolant pump drive belt.
OIL LEAKS
Oil leaks can lead to severe engine damage if the resulting low oil level is not corrected. Besides causing an oily mess where the vehicle is parked, the oil leak can cause blue smoke to occur under the hood as leaking oil drips on the exhaust system. Finding the location of the oil leak can often be difficult. SEE FIGURES 26–3 AND 26–4. To help find the source of oil leaks follow these steps: STEP 1
Clean the engine or area around the suspected oil leak. Use a high-powered hot-water spray to wash the engine. While
the engine is running, spray the entire engine and the engine compartment. Avoid letting the water come into direct contact with the air inlet and ignition distributor or ignition coil(s). NOTE: If the engine starts to run rough or stalls when the engine gets wet, then the secondary ignition wires (spark plug wires) or distributor cap may be defective or have weak insulation. Be certain to wipe all wires and the distributor cap dry with a soft, dry cloth if the engine stalls. An alternative method is to spray a degreaser on the engine, then start and run the engine until warm. Engine heat helps
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FIGURE 26–5 Using a black light to spot leaks after adding dye to the oil. the degreaser penetrate the grease and dirt. Use a water hose to rinse off the engine and engine compartment. STEP 2
STEP 3
FIGURE 26–6 An accessory belt tensioner. Most tensioners have a mark that indicates normal operating location. If the belt has stretched, this indicator mark will be outside of the normal range. Anything wrong with the belt or tensioner can cause noise.
If the oil leak is not visible or oil seems to be coming from “everywhere,” use a white talcum powder. The leaking oil will show as a dark area on the white powder. See the Tech Tip, “The Foot Powder Spray Trick.”
TECH TIP The Foot Powder Spray Trick
Fluorescent dye can be added to the engine oil. Add about 1/2 oz (15 cc) of dye per 5 quarts of engine oil. Start the engine and allow it to run about 10 minutes to thoroughly mix the dye throughout the engine. A black light can then be shown around every suspected oil leak location. The black light will easily show all oil leak locations because the dye will show as a bright yellow/green area. SEE FIGURE 26–5.
The source of an oil or other fluid leak is often difficult to determine. A quick and easy method that works is the following. First, clean the entire area. This can best be done by using a commercially available degreaser to spray the entire area. Let it soak to loosen all accumulated oil and greasy dirt. Clean off the degreaser with a water hose. Let the area dry. Start the engine, and using spray foot powder or other aerosol powder product, spray the entire area. The leak will turn the white powder dark. The exact location of any leak can be quickly located.
NOTE: Fluorescent dye works best with clean oil.
ENGINE NOISE DIAGNOSIS
NOTE: Most oil leaks appear at the bottom of the engine due to gravity. Look for the highest, most forward location for the source of the leak.
An engine knocking noise is often difficult to diagnose. Several items that can cause a deep engine knock include:
Valves clicking. This can happen because of lack of oil to the lifters. This noise is most noticeable at idle when the oil pressure is the lowest. Torque converter. The attaching bolts or nuts may be loose on the flex plate. This noise is most noticeable at idle or when there is no load on the engine.
Cracked flex plate. The noise of a cracked flex plate is often mistaken for a rod- or main-bearing noise.
Loose or defective drive belts or tensioners. If an accessory drive belt is loose or defective, the flopping noise often sounds similar to a bearing knock. SEE FIGURE 26–6.
Piston pin knock. This knocking noise is usually not affected by load on the cylinder. If the clearance is too great, a double knock noise is heard when the engine idles. If all cylinders are grounded out one at a time and the noise does not change, a defective piston pin could be the cause.
Piston slap. A piston slap is usually caused by an undersized or improperly shaped piston or oversized cylinder bore. A
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piston slap is most noticeable when the engine is cold and tends to decrease or stop making noise as the piston expands during engine operation.
Timing chain noise. An excessively loose timing chain can cause a severe knocking noise when the chain hits the timing chain cover. This noise can often sound like a rod-bearing knock.
Rod-bearing noise. The noise from a defective rod bearing is usually load sensitive and changes in intensity as the load on the engine increases and decreases. A rod-bearing failure can often be detected by grounding out the spark plugs one cylinder at a time. If the knocking noise decreases or is eliminated when a particular cylinder is grounded (disabled), then the grounded cylinder is the one from which the noise is originating.
Main-bearing knock. A main-bearing knock often cannot be isolated to a particular cylinder. The sound can vary in intensity and may disappear at times depending on engine load.
OIL PRESSURE GAUGE CRACK
EXHAUST MANIFOLD
FIGURE 26–7 A cracked exhaust manifold on a Ford V-8. OIL PRESSURE SENDING UNIT HOLE
Typical Noises
Possible Causes
Clicking noise—like the clicking of a ballpoint pen
1. Loose spark plug 2. Loose accessory mount (for airconditioning compressor, alternator, power steering pump, etc.) 3. Loose rocker arm 4. Worn rocker arm pedestal 5. Fuel pump (broken mechanical fuel pump return spring) 6. Worn camshaft 7. Exhaust leak SEE FIGURE 26–7.
Clacking noise—like tapping on metal
1. 2. 3. 4.
Worn piston pin Broken piston Excessive valve clearance Timing chain hitting cover
Knock—like knocking 1. Rod bearing(s) on a door 2. Main bearing(s) 3. Thrust bearing(s) 4. Loose torque converter 5. Cracked flex plate (drive plate) Rattle—like a baby rattle
1. 2. 3. 4.
Manifold heat control valve Broken harmonic balancer Loose accessory mounts Loose accessory drive belt or tensioner
Clatter—like rolling marbles
1. Rod bearings 2. Piston pin 3. Loose timing chain
Whine—like an electric motor running
1. 2. 3. 4.
Clunk—like a door closing
Alternator bearing Drive belt Power steering Belt noise (accessory or timing)
1. Engine mount 2. Drive axle shaft U-joint or constant velocity (CV) joint
Regardless of the type of loud knocking noise, after the external causes of the knocking noise have been eliminated, the engine should be disassembled and carefully inspected to determine the exact cause.
FIGURE 26–8 To measure engine oil pressure, remove the oil pressure sending (sender) unit usually located near the oil filter. Screw the pressure gauge into the oil pressure sending unit hole.
TECH TIP Engine Noise and Cost A light ticking noise often heard at one-half engine speed and associated with valve train noise is a less serious problem than many deep-sounding knocking noises. Generally, the deeper the sound of the engine noise, the more the owner will have to pay for repairs. A light “tick tick tick,” though often not cheap, is usually far less expensive than a deep “knock knock knock” from the engine.
OIL PRESSURE TESTING Proper oil pressure is very important for the operation of any engine. Low oil pressure can cause engine wear, and engine wear can cause low oil pressure. If main thrust or rod bearings are worn, oil pressure is reduced because of leakage of the oil around the bearings. Oil pressure testing is usually performed with the following steps. STEP 1
Operate the engine until normal operating temperature is achieved.
STEP 2
With the engine off, remove the oil pressure sending unit or sender, usually located near the oil filter. Thread an oil pressure gauge into the threaded hole. SEE FIGURE 26–8. NOTE: An oil pressure gauge can be made from another gauge, such as an old air-conditioning gauge and a flexible brake hose. The threads are often the same as those used for the oil pressure sending unit.
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TECH TIP Use the KISS Test Method Engine testing is done to find the cause of an engine problem. All the simple things should be tested first. Just remember KISS—“keep it simple, stupid.” A loose alternator belt or loose bolts on a torque converter can sound just like a lifter or rod bearing. A loose spark plug can make the engine perform as if it had a burned valve. Some simple items that can cause serious problems include the following:
PAPER
TAIL PIPE
Oil Burning • Low oil level • Clogged PCV valve or system, causing blowby and oil to be blown into the air cleaner • Clogged drainback passages in the cylinder head • Dirty oil that has not been changed for a long time (Change the oil and drive for about 1,000 miles, or 1,600 km, and change the oil and filter again.)
FIGURE 26–9 The paper test involves holding a piece of paper near the tailpipe of an idling engine. A good engine should produce even, outward puffs of exhaust. If the paper is sucked in toward the tailpipe, a burned valve is a possibility. TECH TIP
Noises The Paper Test
• Carbon on top of the piston(s) can sound like a bad rod bearing (often called a carbon knock) • Loose torque-to-flex plate bolts (or nuts), causing a loud knocking noise
A soundly running engine should produce even and steady exhaust at the tailpipe. You can test this with the paper test. Hold a piece of paper or a 3˝ ⫻ 5˝ index card (even a dollar bill works) within 1 in. (25 mm) of the tailpipe with the engine running at idle. SEE FIGURE 26–9. The paper should blow out evenly without “puffing.” If the paper is drawn toward the tailpipe at times, the exhaust valves in one or more cylinders could be burned. Other reasons why the paper might be sucked toward the tailpipe include the following:
NOTE: Often this problem will cause noise only at idle; the noise tends to disappear during driving or when the engine is under load. • A loose and/or defective drive belt, which may cause a rod- or main-bearing knocking noise (A loose or broken mount for the generator [alternator], power steering pump, or air-conditioning compressor can also cause a knocking noise.)
STEP 3
1. The engine could be misfiring because of a lean condition that could occur normally when the engine is cold. 2. Pulsing of the paper toward the tailpipe could also be caused by a hole in the exhaust system. If exhaust escapes through a hole in the exhaust system, air could be drawn in during the intervals between the exhaust puffs from the tailpipe to the hole in the exhaust, causing the paper to be drawn toward the tailpipe. 3. Ignition fault causing misfire.
Start the engine and observe the gauge. Record the oil pressure at idle and at 2500 RPM. Most vehicle manufacturers recommend a minimum oil pressure of 10 PSI per 1000 RPM. Therefore, at 2500 RPM, the oil pressure should be at least 25 PSI. Always compare your test results with the manufacturer’s recommended oil pressure. Besides engine bearing wear, other possible causes for low oil pressure include: • Low oil level • Diluted oil
COMPRESSION TEST
• Stuck oil pressure relief valve
OIL PRESSURE WARNING LAMP The red oil pressure warning lamp in the dash usually lights when the oil pressure is less than 4 to 7 PSI, depending on vehicle and engine. The oil light should not be on during driving. If the oil warning lamp is on, stop the engine immediately. Always confirm oil pressure with a reliable mechanical gauge before performing engine repairs. The sending unit or circuit may be defective.
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An engine compression test is one of the fundamental engine diagnostic tests that can be performed. For smooth engine operation, all cylinders must have equal compression. An engine can lose compression by leakage of air through one or more of only three routes.
Intake or exhaust valve
Piston rings (or piston, if there is a hole)
Cylinder head gasket
For best results, the engine should be warmed to normal operating temperature before testing. An accurate compression test should be performed as follows: STEP 1
Remove all spark plugs. This allows the engine to be cranked to an even speed. Be sure to label all spark plug wires.
FIGURE 26–10 A two-piece compression gauge set. The threaded hose is screwed into the spark plug hole after removing the spark plug. The gauge part is then snapped onto the end of the hose.
CAUTION: Disable the ignition system by disconnecting the primary leads from the ignition coil or module or by grounding the coil wire after removing it from the center of the distributor cap. Also disable the fuel-injection system to prevent the squirting of fuel into the cylinder. STEP 2
STEP 3
Block open the throttle. This permits the maximum amount of air to be drawn into the engine. This step also ensures consistent compression test results. Thread a compression gauge into one spark plug hole and crank the engine. SEE FIGURE 26–10. Continue cranking the engine through four compression strokes. Each compression stroke makes a puffing sound. NOTE: Note the reading on the compression gauge after the first puff. This reading should be at least one-half the final reading. For example, if the final, highest reading is 150 PSI, then the reading after the first puff should be higher than 75 PSI. A low first-puff reading indicates possible weak piston rings. Release the pressure on the gauge and repeat for the other cylinders.
STEP 4
Record the highest readings and compare the results. Most vehicle manufacturers specify the minimum compression reading and the maximum allowable variation among cylinders. Most manufacturers specify a maximum difference of 20% between the highest reading and the lowest reading. For example: If the high reading is Subtract 20% Lowest allowable compression is
150 PSI ⫺30 PSI 120 PSI
NOTE: To make the math quick and easy, think of 10% of 150, which is 15 (move the decimal point to the left one place). Now double it: 15 ⫻ 2 ⫽ 30. This represents 20%. NOTE: During cranking, the oil pump cannot maintain normal oil pressure. Extended engine cranking, such as that which occurs during a compression test, can cause hydraulic lifters to collapse. When the engine starts, loud valve clicking noises may be heard. This should be considered normal after performing a compression test, and the noise should stop after the vehicle has been driven a short distance.
SPARK PLUG
RUBBER HOSE
FIGURE 26–11 Use a vacuum or fuel line hose over the spark plug to install it without danger of cross-threading the cylinder head.
TECH TIP The Hose Trick Installing spark plugs can be made easier by using a rubber hose on the end of the spark plug. The hose can be a vacuum hose, fuel line, or even an old spark plug wire end. SEE FIGURE 26–11. The hose makes it easy to start the threads of the spark plug into the cylinder head. After starting the threads, continue to thread the spark plug for several turns. Using the hose eliminates the chance of crossthreading the plug. This is especially important when installing spark plugs in aluminum cylinder heads.
WET COMPRESSION TEST If the compression test reading indicates low compression on one or more cylinders, add three squirts of oil to the cylinder and retest. This is called a wet compression test, when oil is used to help seal around the piston rings. CAUTION: Do not use more oil than three squirts from a hand-operated oil squirt can. Too much oil can cause a hydrostatic lock, which can damage or break pistons or connecting rods or even crack a cylinder head. Perform the compression test again and observe the results. If the first-puff readings greatly improve and the readings are much higher than without the oil, the cause of the low compression is worn or defective piston rings. If the compression readings increase only slightly (or not at all), then the cause of the low compression is usually defective valves. SEE FIGURE 26–12. NOTE: During both the dry and wet compression tests, be sure that the battery and starting system are capable of cranking the engine at normal cranking speed.
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FIGURE 26–13 A typical handheld cylinder leakage tester. FIGURE 26–12 Badly burned exhaust valve. A compression test could have detected a problem, and a cylinder leakage test (leak-down test) could have been used to determine the exact problem.
RUNNING (DYNAMIC) COMPRESSION TEST A compression test is commonly used to help determine engine condition and is usually performed with the engine cranking. What is the RPM of a cranking engine? An engine idles at about 600 to 900 RPM, and the starter motor obviously cannot crank the engine as fast as the engine idles. Most manufacturers’ specifications require the engine to crank at 80 to 250 cranking RPM. Therefore, a check of the engine’s compression at cranking speed determines the condition of an engine that does not run at such low speeds. But what should be the compression of a running engine? Some would think that the compression would be substantially higher, because the valve overlap of the cam is more effective at higher engine speeds, which would tend to increase the compression. A running compression test, also called a dynamic compression test, is done with the engine running rather than during engine cranking as is done in a regular compression test. Actually, the compression pressure of a running engine is much lower than cranking compression pressure. This results from the volumetric efficiency. The engine is revolving faster, and therefore, there is less time for air to enter the combustion chamber. With less air to compress, the compression pressure is lower. Typically, the higher the engine RPM, the lower the running compression. For most engines, the value ranges are as follows:
Compression during cranking:
125 to 160 PSI
Compression at idle:
60 to 90 PSI
Compression at 2,000 RPM:
30 to 60 PSI
As with cranking compression, the running compression of all cylinders should be equal. Therefore, a problem is not likely to be detected by single compression values, but by variations in running compression values among the cylinders. Broken valve springs, worn valve guides, bent pushrods, and worn cam lobes are some items that would be indicated by a low running compression test reading on one or more cylinders.
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FIGURE 26–14 A whistle stop used to find top dead center. Remove the spark plug and install the whistle stop, then rotate the engine by hand. When the whistle stops making a sound, the piston is at the top.
PERFORMING A RUNNING COMPRESSION TEST
To perform a running compression test, remove just one spark plug at a time. With one spark plug removed from the engine, use a jumper wire to ground the spark plug wire to a good engine ground. This prevents possible ignition coil damage. Start the engine, push the pressure release on the gauge, and read the compression. Increase the engine speed to about 2,000 RPM and push the pressure release on the gauge again. Read the gauge. Stop the engine, reinstall the spark plug, reattach the spark plug wire, and repeat the test for each of the remaining cylinders. Just like the cranking compression test, the running compression test can inform a technician of the relative compression of all the cylinders.
CYLINDER LEAKAGE TEST One of the best tests that can be used to determine engine condition is the cylinder leakage test. This test involves injecting air under pressure into the cylinders one at a time. The amount and location of any escaping air helps the technician determine the condition of the engine. The air is injected into the cylinder through a cylinder leakage gauge into the spark plug hole. SEE FIGURE 26–13. To perform the cylinder leakage test, take the following steps: STEP 1
For best results, the engine should be at normal operating temperature (upper radiator hose hot and pressurized).
STEP 2
The cylinder being tested must be at top dead center (TDC) of the compression stroke. SEE FIGURE 26–14.
NOTE: The greatest amount of wear occurs at the top of the cylinder because of the heat generated near the top of the cylinders. The piston ring flex also adds to the wear at the top of the cylinder. STEP 3
Calibrate the cylinder leakage unit as per manufacturer’s instructions.
STEP 4
Inject air into the cylinders one at a time, rotating the engine as necessitated by firing order to test each cylinder at TDC on the compression stroke.
STEP 5
Evaluate the results: Less than 10% leakage: good Less than 20% leakage: acceptable Less than 30% leakage: poor More than 30% leakage: definite problem NOTE: If leakage seems unacceptably high, repeat the test, being certain that it is being performed correctly and that the cylinder being tested is at TDC on the compression stroke.
STEP 6
Check the source of air leakage. a. If air is heard escaping from the oil filler cap, the piston rings are worn or broken. b. If air is observed bubbling out of the radiator, there is a possible blown head gasket or cracked cylinder head. c. If air is heard coming from the throttle body or air inlet on fuel-injection-equipped engines, there is a defective intake valve(s). d. If air is heard coming from the tailpipe, there is a defective exhaust valve(s).
CYLINDER POWER BALANCE TEST Most large engine analyzers and scan tools have a cylinder power balance feature. The purpose of a cylinder power balance test is to determine if all cylinders are contributing power equally. It determines this by shorting out one cylinder at a time. If the engine speed (RPM) does not drop as much for one cylinder as for other cylinders of the same engine, then the shorted cylinder must be weaker than the other cylinders. For example: Cylinder Number
SPARK PLUG WIRE
TEST LIGHT
3" PIECE OF HOSE
FIGURE 26–15 Using a vacuum hose and a test light to ground one cylinder at a time on a distributorless ignition system. This works on all types of ignition systems and provides a method for grounding out one cylinder at a time without fear of damaging any component. To avoid possible damage to the catalytic converter, do not short out a cylinder for longer than five seconds.
POWER BALANCE TEST PROCEDURE When point-type ignition was used on all vehicles, the common method for determining which, if any, cylinder was weak was to remove a spark plug wire from one spark plug at a time while watching a tachometer and a vacuum gauge. This method is not recommended on any vehicle with any type of electronic ignition. If any of the spark plug wires are removed from a spark plug with the engine running, the ignition coil tries to supply increasing levels of voltage attempting to jump the increasing gap as the plug wires are removed. This high voltage could easily track the ignition coil, damage the ignition module, or both. The acceptable method of canceling cylinders, which will work on all types of ignition systems, including distributorless, is to ground the secondary current for each cylinder. SEE FIGURE 26–15. The cylinder with the least RPM drop is the cylinder not producing its share of power.
RPM Drop When Ignition Is Shorted
1
75
2
70
3
15
4
65
5
75
6
70
Cylinder 3 is the weak cylinder. NOTE: Most automotive test equipment uses automatic means for testing cylinder balance. Be certain to correctly identify the offending cylinder. Cylinder 3 as identified by the equipment may be the third cylinder in the firing order instead of the actual cylinder 3.
VACUUM TESTS Vacuum is pressure below atmospheric pressure and is measured in inches (or millimeters) of mercury (Hg). An engine in good mechanical condition will run with high manifold vacuum. Manifold vacuum is developed by the pistons as they move down on the intake stroke to draw the charge from the throttle body and intake manifold. Air to refill the manifold comes past the throttle plate into the manifold. Vacuum will increase anytime the engine turns faster or has better cylinder sealing while the throttle plate remains in a fixed position. Manifold vacuum will decrease when the engine turns more slowly or when the cylinders no longer do an efficient job of pumping.
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10 20
Vacuum in Hg
30
10
0 5 Pressure P.S.I.
10
20
Vacuum in Hg
0 5 Pressure P.S.I.
30
10
FIGURE 26–17 A steady but low reading could indicate retarded valve or ignition timing.
10
FIGURE 26–16 An engine in good mechanical condition should produce 17 to 21 in. Hg of vacuum at idle at sea level.
20
Vacuum in Hg
0 5
30
Pressure P.S.I.
10
Vacuum tests include testing the engine for cranking vacuum, idle vacuum, and vacuum at 2,500 RPM.
CRANKING VACUUM TEST
Measuring the amount of manifold vacuum during cranking is a quick and easy test to determine if the piston rings and valves are properly sealing. (For accurate results, the engine should be warm and the throttle closed.) To perform the cranking vacuum test, take the following steps. STEP 1
Disable the ignition or fuel injection.
STEP 2
Connect the vacuum gauge to a manifold vacuum source.
STEP 3
Crank the engine while observing the vacuum gauge.
Cranking vacuum should be higher than 2.5 in. Hg. (Normal cranking vacuum is 3 to 6 in. Hg.) If it is lower than 2.5 in. Hg, then the following could be the cause.
Too slow a cranking speed
Worn piston rings
Leaking valves
Excessive amounts of air bypassing the throttle plate (This could give a false low vacuum reading. Common sources include a throttle plate partially open or a high-performance camshaft with excessive overlap.)
IDLE VACUUM TEST
An engine in proper condition should idle with a steady vacuum between 17 and 21 in. Hg. SEE FIGURE 26–16.
NOTE: Engine vacuum readings vary with altitude. A reduction of 1 in. Hg per 1,000 ft (300 m) of altitude should be subtracted from the expected values if testing a vehicle above 1,000 ft (300 m).
LOW AND STEADY VACUUM
If the vacuum is lower than normal, yet the gauge reading is steady, the most common causes include:
Retarded ignition timing
Retarded cam timing (check timing chain for excessive slack or timing belt for proper installation) SEE FIGURE 26–17.
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FIGURE 26–18 A gauge reading with the needle fluctuating 3 to 9 in. Hg below normal often indicates a vacuum leak in the intake system.
10 20
Vacuum in Hg
30
0 5 Pressure P.S.I.
10
FIGURE 26–19 A leaking head gasket can cause the needle to vibrate as it moves through a range from below to above normal.
FLUCTUATING VACUUM
If the needle drops, then returns to a normal reading, then drops again, and again returns, this indicates a sticking valve. A common cause of sticking valves is lack of lubrication of the valve stems. SEE FIGURES 26–18 THROUGH 26–26. If the vacuum gauge fluctuates above and below a center point, burned valves or weak valve springs may be indicated. If the fluctuation is slow and steady, unequal fuel mixture could be the cause. NOTE: A common trick that some technicians use is to squirt some automatic transmission fluid (ATF) down the throttle body or into the air inlet of a warm engine. Often the idle quality improves and normal vacuum gauge readings are restored. The use of ATF does create excessive exhaust smoke for a short time, but it should not harm oxygen sensors or catalytic converters.
10 20
Vacuum in Hg
10 0 20
Vacuum in Hg
5
5 Pressure P.S.I.
30
Pressure P.S.I.
30
10
10
FIGURE 26–20 An oscillating needle 1 or 2 in. Hg below normal could indicate an incorrect air-fuel mixture (either too rich or too lean).
FIGURE 26–24 A steady needle reading that drops 2 or 3 in. Hg when the engine speed is increased slightly above idle indicates that the ignition timing is retarded.
10 10 20
0
Vacuum in Hg
20 5
10 Vacuum in Hg
0
10
10 20
Pressure P.S.I.
30
10
10 Vacuum in Hg
Vacuum in Hg
30
FIGURE 26–22 If the needle drops 1 or 2 in. Hg from the normal reading, one of the engine valves is burned or not seating properly.
30
5 Pressure P.S.I.
FIGURE 26–25 A steady needle reading that rises 2 or 3 in. Hg when the engine speed is increased slightly above idle indicates that the ignition timing is advanced.
5
20
0
10
FIGURE 26–21 A rapidly vibrating needle at idle that becomes steady as engine speed is increased indicates worn valve guides.
20
Vacuum in Hg
30
Pressure P.S.I.
30
0
0 5 Pressure P.S.I.
10
FIGURE 26–26 A needle that drops to near zero when the engine is accelerated rapidly and then rises slightly to a reading below normal indicates an exhaust restriction.
EXHAUST RESTRICTION TEST
0 5 Pressure P.S.I.
10
If the exhaust system is restricted, the engine will be low on power, yet smooth. Common causes of restricted exhaust include the following:
FIGURE 26–23 Weak valve springs will produce a normal reading at idle, but as engine speed increases, the needle will fluctuate rapidly between 12 and 24 in. Hg.
Clogged catalytic converter. Always check the ignition and fuel-injection systems for faults that could cause excessive amounts of unburned fuel to be exhausted. Excessive unburned fuel can overheat the catalytic converter and cause the beads or structure of the converter to fuse together, creating the restriction. A defective fuel delivery system could also cause excessive unburned fuel to be dumped into the converter.
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Clogged or restricted muffler. This can cause low power. Often a defective catalytic converter will shed particles that can clog a muffler. Broken internal baffles can also restrict exhaust flow.
Damaged or defective piping. This can reduce the power of any engine. Some exhaust pipe is constructed with double walls, and the inside pipe can collapse and form a restriction that is not visible on the outside of the exhaust pipe.
TESTING BACK PRESSURE WITH A VACUUM GAUGE
FIGURE 26–27 A technician-made adapter used to test exhaust system back pressure.
A vacuum gauge can be used to measure manifold vacuum at a high idle (2000 to 2500 RPM). If the exhaust system is restricted, pressure increases in the exhaust system. This pressure is called back pressure. Manifold vacuum will drop gradually if the engine is kept at a constant speed if the exhaust is restricted. The reason the vacuum will drop is that all exhaust leaving the engine at the higher engine speed cannot get through the restriction. After a short time (within one minute), the exhaust tends to “pile up” above the restriction and eventually remains in the cylinder of the engine at the end of the exhaust stroke. Therefore, at the beginning of the intake stroke, when the piston traveling downward should be lowering the pressure (raising the vacuum) in the intake manifold, the extra exhaust in the cylinder lowers the normal vacuum. If the exhaust restriction is severe enough, the vehicle can become undriveable because cylinder filling cannot occur except at idle.
TESTING BACK PRESSURE WITH A PRESSURE GAUGE
With an oxygen sensor. Use a back pressure gauge and adapter or remove the inside of an old, discarded oxygen sensor and thread in an adapter to convert to a vacuum or pressure gauge.
With the exhaust gas recirculation (EGR) valve. Remove the EGR valve and fabricate a plate to connect to a pressure gauge. NOTE: An adapter can be easily made by inserting a metal tube or pipe. A short section of brake line works great. The pipe can be brazed to the oxygen sensor housing or it can be glued in with epoxy. An 18 mm compression gauge adapter can also be adapted to fit into the oxygen sensor opening. SEE FIGURE 26–27.
With the air-injection reaction (AIR) check valve. Remove the check valve from the exhaust tubes leading down to the exhaust manifold. Use a rubber cone with a tube inside to seal against the exhaust tube. Connect the tube to a pressure gauge. Exhaust system back pressure can be measured directly by installing a pressure gauge into an exhaust opening. This can be accomplished in one of the following ways.
At idle, the maximum back pressure should be less than 1.5 PSI (10 kPa), and it should be less than 2.5 PSI (15 kPa) at 2500 RPM.
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FIGURE 26–28 A tester that uses a blue liquid to check for exhaust gases in the exhaust, which would indicate a head gasket leak problem.
DIAGNOSING HEAD GASKET FAILURE Several items can be used to help diagnose a head gasket failure.
Exhaust gas analyzer. With the radiator cap removed, place the probe from the exhaust analyzer above the radiator filler neck. If the HC reading increases, the exhaust (unburned hydrocarbons) is getting into the coolant from the combustion chamber.
Chemical test. A chemical tester using blue liquid is also available. The liquid turns yellow if combustion gases are present in the coolant. SEE FIGURE 26–28.
Bubbles in the coolant. Remove the coolant pump belt to prevent pump operation. Remove the radiator cap and start the engine. If bubbles appear in the coolant before it begins to boil, a defective head gasket or cracked cylinder head is indicated.
Excessive exhaust steam. If excessive water or steam is observed coming from the tailpipe, this means that coolant is getting into the combustion chamber from a defective head gasket or a cracked head. If there is leakage between cylinders, the engine usually misfires and a power balancer test and/or compression test can be used to confirm the problem.
If any of the preceding indicators of head gasket failure occur, remove the cylinder head(s) and check all of the following: 1. Head gasket 2. Sealing surfaces—for warpage 3. Castings—for cracks NOTE: A leaking thermal vacuum valve can cause symptoms similar to those of a defective head gasket. Most thermal vacuum valves thread into a coolant passage, and they often leak only after they get hot.
COOLANT TEMPERATURE LIGHT
Most vehicles are equipped with a coolant temperature gauge or dash warning light. The warning light may be labeled “coolant,” “hot,” or “temperature.” If the coolant temperature warning light comes on during driving, this usually indicates that the coolant temperature is above a safe level, or above about 250°F (120°C). Normal coolant temperature should be about 200°F to 220°F (90°C to 105°C). If the coolant temperature light comes on during driving, the following steps should be followed to prevent possible engine damage. 1. Turn off the air conditioning and turn on the heater. The heater will help get rid of some of the heat in the cooling system.
DASH WARNING LIGHTS Most vehicles are equipped with several dash warning lights often called “telltale” or “idiot” lights. These lights are often the only warning a driver receives that there may be engine problems. A summary of typical dash warning lights and their meanings follows.
OIL (ENGINE) LIGHT The red oil light indicates that the engine oil pressure is too low (usually lights when oil pressure is 4 to 7 PSI [20 to 50 kPa]). Normal oil pressure should be 10 to 60 PSI (70 to 400 kPa) or 10 PSI per 1000 engine RPM. When this light comes on, the driver should shut off the engine immediately and check the oil level and condition for possible dilution with gasoline caused by a fuel system fault. If the oil level is okay, then there is a possible serious engine problem or a possible defective oil pressure sending (sender) unit. The automotive technician should always check the oil pressure using a reliable mechanical oil pressure gauge if low oil pressure is suspected.
2. Raise the engine speed in neutral or park to increase the circulation of coolant through the radiator. 3. If possible, turn the engine off and allow it to cool (this may take over an hour). 4. Do not continue driving with the coolant temperature light on (or the gauge reading in the red warning section or above 260°F) or serious engine damage may result. NOTE: If the engine does not feel or smell hot, it is possible that the problem is a faulty coolant temperature sensor or gauge.
TECH TIP Misfire Diagnosis If a misfire goes away with propane added to the air inlet, suspect a lean injector.
NOTE: Some automobile manufacturers combine the dash warning lights for oil pressure and coolant temperature into one light, usually labeled “engine.” Therefore, when the engine light comes on, the technician should check for possible coolant temperature and/or oil pressure problems.
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COMPRESSION TEST
1
The tools and equipment needed to perform a compression test include a compression gauge, an air nozzle, and the socket ratchets and extensions that may be necessary to remove the spark plugs from the engine.
3
Block open the throttle (and choke, if the engine is equipped with a carburetor). Here a screwdriver is being used to wedge the throttle linkage open. Keeping the throttle open ensures that enough air will be drawn into the engine so that the compression test results will be accurate.
5
Remove all of the spark plugs. Be sure to mark the spark plug wires so that they can be reinstalled onto the correct spark plugs after the compression test has been performed.
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2
To prevent ignition and fuel-injection operation while the engine is being cranked, remove both the fuelinjection fuse and the ignition fuse. If the fuses cannot be removed, disconnect the wiring connectors for the injectors and the ignition system.
4
Before removing the spark plugs, use an air nozzle to blow away any dirt that may be around the spark plug. This step helps prevent debris from getting into the engine when the spark plugs are removed.
6
Select the proper adapter for the compression gauge. The threads on the adapter should match those on the spark plug.
STEP BY STEP
7
If necessary, connect a battery charger to the battery before starting the compression test. It is important that consistent cranking speed be available for each cylinder being tested.
9
After the engine has been cranked for four “puffs,” stop cranking the engine and observe the compression gauge.
11
If a cylinder(s) is lower than most of the others, use an oil can and squirt two squirts of engine oil into the cylinder and repeat the compression test. This is called performing a wet compression test.
8
Make a note of the reading on the gauge after the first “puff,” which indicates the first compression stroke that occurred on that cylinder as the engine was being rotated. If the first puff reading is low and the reading gradually increases with each puff, weak or worn piston rings may be indicated.
10
12
Record the first puff and this final reading for each cylinder. The final readings should all be within 20% of each other.
If the gauge reading is now much higher than the first test results, then the cause of the low compression is due to worn or defective piston rings. The oil in the cylinder temporarily seals the rings which causes the higher reading.
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REVIEW QUESTIONS 1. Describe the visual checks that should be performed on an engine if a mechanical malfunction is suspected. 2. List three simple items that could cause excessive oil consumption. 3. List three simple items that could cause engine noises. 4. Describe how to perform a compression test and how to determine what is wrong with an engine based on a compression test result.
5. Describe the cylinder leakage test. 6. Describe how a vacuum gauge would indicate if the valves were sticking in their guides. 7. Describe the test procedure for determining if the exhaust system is restricted (clogged) using a vacuum gauge.
CHAPTER QUIZ 1. Technician A says that the paper test could detect a burned valve. Technician B says that a grayish white stain on the engine could be a coolant leak. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 2. Two technicians are discussing oil leaks. Technician A says that an oil leak can be found using a fluorescent dye in the oil with a black light to check for leaks. Technician B says that a white spray powder can be used to locate oil leaks. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 3. Which of the following is the least likely to cause an engine noise? a. Carbon on the pistons b. Cracked exhaust manifold c. Loose accessory drive belt d. Vacuum leak 4. A good engine should produce how much compression during a running (dynamic) compression test at idle? a. 150 to 200 PSI c. 60 to 90 PSI b. 100 to 150 PSI d. 30 to 60 PSI 5. A smoothly operating engine depends on ______________. a. High compression on most cylinders b. Equal compression between cylinders c. Cylinder compression levels above 100 PSI (700 kPa) and within 70 PSI (500 kPa) of each other d. Compression levels below 100 PSI (700 kPa) on most cylinders
chapter
27
6. A good reading for a cylinder leakage test would be ______________. a. Within 20% between cylinders b. All cylinders below 20% leakage c. All cylinders above 20% leakage d. All cylinders above 70% leakage and within 7% of each other 7. Technician A says that during a power balance test, the cylinder that causes the biggest RPM drop is the weak cylinder. Technician B says that if one spark plug wire is grounded out and the engine speed does not drop, a weak or dead cylinder is indicated. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 8. Cranking vacuum should be ______________. a. 2.5 in. Hg or higher c. 17 to 21 in. Hg b. Over 25 in. Hg d. 6 to 16 in. Hg 9. Technician A says that a leaking head gasket can be tested for using a chemical tester. Technician B says that leaking head gasket can be found using an exhaust gas analyzer. a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 10. The low oil pressure warning light usually comes on ______________. a. Whenever an oil change is required b. Whenever oil pressure drops dangerously low (4 to 7 PSI) c. Whenever the oil filter bypass valve opens d. Whenever the oil filter antidrainback valve opens
IN-VEHICLE ENGINE SERVICE
OBJECTIVES: After studying Chapter 27, the reader should be able to: • Prepare for ASE certification test content area “A” (General Engine Diagnosis). • Diagnose and replace the thermostat. • Diagnose and replace the water pump. • Diagnose and replace an intake manifold gasket. • Determine and verify correct cam timing. • Replace a timing a belt. • Describe how to adjust valves. • Explain hybrid engine precautions. KEY TERMS: EREV 255 • Fretting 254 • HEV 255 • Idle stop 255 • Skewed 253
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JIGGLE VALVE
FIGURE 27–1 If the thermostat has a jiggle valve, it should be placed toward the top to allow air to escape. If a thermostat were to become stuck open or open too soon, this can set a diagnostic trouble code P0128 (coolant temperature below thermostat regulating temperature).
FIGURE 27–2 Use caution if using a steel scraper to remove a gasket from aluminum parts. It is best to use a wood or plastic scraper.
STEP 6
Refill the cooling system with the specified coolant and bleed any trapped air from the system.
STEP 7
Pressurize the cooling system to verify that there are no leaks around the thermostat housing.
STEP 8
Run the engine until it reaches normal operating temperature and check for leaks.
STEP 9
Verify that the engine is reaching correct operating temperature.
THERMOSTAT REPLACEMENT FAILURE PATTERNS All thermostat valves move during operation to maintain the desired coolant temperature. Thermostats can fail in the following ways.
Stuck open. If a thermostat fails open or partially open, the operating temperature of the engine will be less than normal. SEE FIGURE 27–1.
Stuck closed. If the thermostat fails closed or almost closed, the engine will likely overheat.
Stuck partially open. This will cause the engine to warm up slowly if at all. This condition can cause the powertrain control module (PCM) to set a P0128 diagnostic trouble code (DTC) which means that the engine coolant temperature does not reach the specified temperature.
Skewed. A skewed thermostat works, but not within the correct temperature range. Therefore, the engine could overheat or operate cooler than normal or even do both.
REPLACEMENT PROCEDURE Before replacing the thermostat, double-check that the cooling system problem is not due to another fault, such as being low on coolant or an inoperative cooling fan. Check service information for the specified procedure to follow to replace the thermostat. Most recommended procedures include the following steps. STEP 1
Allow the engine to cool for several hours so the engine and the coolant should be at room temperature.
STEP 2
Drain the coolant into a suitable container. Most vehicle manufacturers recommend that new coolant be used and the old coolant disposed of properly or recycled.
WATER PUMP REPLACEMENT NEED FOR REPLACEMENT
A water pump will require replacement if any of the following conditions are present.
Leaking coolant from the weep hole
Bearing noisy or loose
Lack of proper coolant flow caused by worn or slipping impeller blades
REPLACEMENT GUIDELINES After diagnosis has been confirmed that the water pump requires replacement, check service information for the exact procedure to follow. The steps usually include the following: STEP 1
Allow the engine to cool to room temperature.
STEP 2
Drain the coolant and dispose of properly or recycle.
STEP 3
Remove engine components to gain access to the water pump as specified in service information.
STEP 4
Remove the water pump assembly.
STEP 5
Clean the gasket surfaces and install the new water pump using a new gasket or seal as needed. SEE FIGURE 27–2. Torque all fasteners to factory specifications.
STEP 3
Remove any necessary components to get access to the thermostat.
STEP 4
Remove the thermostat housing and thermostat.
STEP 6
Install removed engine components.
STEP 5
Replace the thermostat housing gasket and thermostat. Torque all fasteners to specifications.
STEP 7
Fill the cooling system with the specified coolant.
STEP 8
Run the engine, check for leaks, and verify proper operation.
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FIGURE 27–3 An intake manifold gasket that failed and allowed coolant to be drawn into the cylinder(s).
INTAKE MANIFOLD GASKET INSPECTION
FIGURE 27–4 The lower intake manifold attaches to the cylinder heads.
CAUSES OF FAILURE Many V-type engines leak oil, coolant, or experience an air (vacuum) leak caused by a leaking intake manifold gasket. This failure can be contributed to one or more of the following: 1. Expansion/contraction rate difference between the cast-iron head and the aluminum intake manifold can cause the intake manifold gasket to be damaged by the relative motion of the head and intake manifold. This type of failure is called fretting. 2. Plastic (Nylon 6.6) gasket deterioration caused by the coolant. SEE FIGURE 27–3.
DIAGNOSIS OF LEAKING INTAKE MANIFOLD GASKET Because intake manifold gaskets are used to seal oil, air, and coolant in most causes, determining that the intake manifold gasket is the root cause can be a challenge. To diagnose a possible leaking intake manifold gasket, perform the following tests. Visual inspection. Check for evidence of oil or coolant between the intake manifold and the cylinder heads. Coolant level. Check the coolant level and determine if the level has been dropping. A leaking intake manifold gasket can cause coolant to leak and then evaporate, leaving no evidence of the leak. Air (vacuum) leak. If there is a stored diagnostic trouble code (DTC) for a lean exhaust (P0171, P0172, or P0174), a leaking intake manifold gasket could be the cause. Use propane to check if the engine changes when dispensed around the intake manifold gasket. If the engine changes in speed or sound, then this test verifies that an air leak is present.
INTAKE MANIFOLD GASKET REPLACEMENT When replacing the intake manifold gasket, always check service information for the exact procedure to follow. The steps usually include the following: STEP 1
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Be sure the engine has been off for about an hour and then drain the coolant into a suitable container.
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FIGURE 27–5 The upper intake manifold, often called a plenum, attaches to the lower intake manifold. STEP 2
Remove covers and other specified parts needed to get access to the retaining bolts.
STEP 3
To help ensure that the manifold does not warp when removed, loosen all fasteners in the reverse order of the tightening sequence. This means that the bolts should be loosened starting at the ends and working toward the center.
STEP 4
Remove the upper intake manifold (plenum), if equipped, and inspect for faults. SEE FIGURES 27–4 AND 27–5.
STEP 5
Remove the lower intake manifold, using the same bolt removal procedure of starting at the ends and working toward the center.
STEP 6
Thoroughly clean the area and replace the intake manifold if needed. Check that the correct replacement manifold is being used, and even the current part could look different from the original. SEE FIGURE 27–6.
STEP 7
Install the intake manifold using new gaskets as specified. Some designs use gaskets that are reusable. Replace as needed.
STEP 8
Torque all fasteners to factory specifications and in the proper sequences. The tightening sequences usually start at the center and work outward to the ends. CAUTION: Double-check the torque specifications and be sure to use the correct values. Many intake manifolds use fasteners that are torqued to values expressed in pound-inches and not pound-feet.
FIGURE 27–6 Many aftermarket replacement intake manifolds have a different appearance from the original manifold. STEP 9
Reinstall all parts needed to allow the engine to start and run, including refilling the coolant if needed.
STEP 10 Start the engine and check for leaks and proper engine operation. STEP 11 Reset or relearn the idle if specified, using a scan tool.
FIGURE 27–7 A single overhead camshaft engine with a timing belt that also rotates the water pump.
STEP 12 Install all of the remaining parts and perform a test drive to verify proper operation and no leaks.
STEP 5
Replace the timing belt and any other recommended items. Components that some vehicle manufacturers recommend replacing in addition to the timing belt include: • Tensioner assembly • Water pump • Camshaft oil seal(s) • Front crankshaft seal
STEP 6
Check (verify) that the camshaft timing is correct by rotating the engine several revolutions.
STEP 7
Install enough components to allow the engine to start to verify proper operation. Check for any leaks, especially if seals have been replaced.
STEP 8
Complete the reassembly of the engine and perform a test drive before returning the vehicle to the customer.
STEP 13 Check and replace the air filter if needed. STEP 14 Change the engine oil if the intake manifold leak could have caused coolant to leak into the engine, which would contaminate the oil.
TIMING BELT REPLACEMENT NEED FOR REPLACEMENT Timing belts have a limited service and a specified replacement interval ranging from 60,000 miles (97,000 km) to about 100,000 miles (161,000 km). Timing belts are required to be replaced if any of the following conditions occur.
Meets or exceeds the vehicle manufacturer’s recommended timing belt replacement interval.
The timing belt has been contaminated with coolant or engine oil.
The timing belt has failed (missing belt teeth or broken).
TIMING BELT REPLACEMENT GUIDELINES
Before replacing the timing belt, check service information for the recommended procedure to follow. Most timing belt replacement procedures include the following steps. STEP 1
Allow the engine to cool before starting to remove components to help eliminate the possibility of personal injury or warpage of the parts.
STEP 2
Remove all necessary components to gain access to the timing belt and timing marks.
STEP 3
STEP 4
If the timing belt is not broken, rotate the engine until the camshaft and crankshaft timing marks are aligned according to the specified marks. SEE FIGURE 27–7. Loosen or remove the tensioner as needed to remove the timing belt.
HYBRID ENGINE PRECAUTIONS HYBRID VEHICLE ENGINE OPERATION
Gasoline engines used in hybrid electric vehicles (HEVs) and in extended range electric vehicles (EREVs) can be a hazard to be around under some conditions. These vehicles are designed to stop the gasoline engines unless needed. This feature is called idle stop. This means that the engine is not running, but could start at any time if the computer detects the need to charge the hybrid batteries or other issue that requires the gasoline engine to start and run.
PRECAUTIONS Always check service information for the exact procedures to follow when working around or under the hood of a hybrid electric vehicle. These precautions could include:
Before working under the hood or around the engine, be sure that the ignition is off and the key is out of the ignition. Check that the “Ready” light is off. SEE FIGURE 27–8.
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FIGURE 27–8 A Toyota/Lexus hybrid electric vehicle has a ready light. If the ready light is on, the engine can start at anytime without warning.
Do not touch any circuits that have orange electrical wires or conduit. The orange color indicates dangerous high-voltage wires, which could cause serious injury or death if touched. Always use high-voltage linesman’s gloves whenever depowering the high-voltage system.
HYBRID ENGINE SERVICE
The gasoline engine in most hybrid electric vehicles specifies low viscosity engine oil as a way to achieve maximum fuel economy. SEE FIGURE 27–9. The viscosity required is often:
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FIGURE 27–9 Always use the viscosity of oil as specified on the oil fill cap.
SAE 0W-20
SAE 5W-20
Many shops do not keep this viscosity in stock so preparations need to be made to get and use the specified engine oil. In addition to engine oil, some hybrid electric vehicles such as the Honda Insight (1999–2004) require special spark plugs. Check service information for the specified service procedures and parts needed if a hybrid electric vehicle is being serviced.
VALVE ADJUSTMENT
1
Before starting the process of adjusting the valves, look up the specifications and exact procedures. The technician is checking this information from a computer CD-ROM-based information system.
2
The tools necessary to adjust the valves on an engine with adjustable rocker arms include basic hand tools, feeler gauge, and a torque wrench.
3
An overall view of the 4-cylinder engine that is due for a scheduled valve adjustment according to the vehicle manufacturer’s recommendations.
4
Start the valve adjustment procedure by first disconnecting and labeling, if necessary, all vacuum lines that need to be removed to gain access to the valve cover.
5
The air intake tube is being removed from the throttle body.
6
With all vacuum lines and the intake tube removed, the valve cover can be removed after removing all retaining bolts.
CONTINUED
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VALVE ADJUSTMENT
7
(CONTINUED)
Notice how clean the engine appears. This is a testament of proper maintenance and regular oil changes by the owner.
8
To help locate how far the engine is being rotated, the technician is removing the distributor cap to be able to observe the position of the rotor.
TIMING PLATE WITH DEGREES
9
The engine is rotated until the timing marks on the front of the crankshaft line up with zero degrees—top dead center (TDC)—with both valves closed on #1 cylinder.
11 258
If the valve clearance (lash) is not correct, loosen the retaining nut and turn the valve adjusting screw with a screwdriver to achieve the proper clearance.
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10
With the rocker arms contacting the base circle of the cam, insert a feeler gauge of the specified thickness between the camshaft and the rocker arm. There should be a slight drag on the feeler gauge.
12
After adjusting the valves that are closed, rotate the engine one full rotation until the engine timing marks again align.
STEP BY STEP
13
The engine is rotated until the timing marks again align indicating that the companion cylinder will now be in position for valve clearance measurement.
14
On some engines, it is necessary to watch the direction the rotor is pointing to help determine how far to rotate the engine. Always follow the vehicle manufacturer’s recommended procedure.
15
The technician is using a feeler gauge that is one-thousandth of an inch thinner and another onethousandth of an inch thicker than the specified clearance as a double-check that the clearance is correct.
16
Adjusting a valve takes both hands—one to hold the wrench to loosen and tighten the lock nut and one to turn the adjusting screw. Always double check the clearance after an adjustment is made.
17
After all valves have been properly measured and adjusted as necessary, start the reassembly process by replacing all gaskets and seals as specified by the vehicle manufacturer.
18
Reinstall the valve cover being careful to not pinch a wire or vacuum hose between the cover and the cylinder head.
CONTINUED
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VALVE ADJUSTMENT
(CONTINUED)
19
Use a torque wrench and torque the valve cover retaining bolts to factory specifications.
20
Reinstall the distributor cap.
21
Reinstall the spark plug wires and all brackets that were removed to gain access to the valve cover.
22
Reconnect all vacuum and air hoses and tubes. Replace any vacuum hoses that are brittle or swollen with new ones.
23
Be sure that the clips are properly installed. Start the engine and check for proper operation.
24
Double-check for any oil or vacuum leaks after starting the engine.
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REVIEW QUESTIONS 1. How can a thermostat fail?
4. Why must timing belts be replaced?
2. How can a water pump fail requiring replacement?
5. Why is it important that the READY light be out on the dash before working under the hood of a hybrid electric vehicle?
3. What will happen to the engine if the intake manifold gasket fails?
CHAPTER QUIZ 1. A thermostat can fail in which way? a. Stuck open b. Stuck closed c. Stuck partially open d. Any of the above 2. A skewed thermostat means it is ______________. a. Working, but not at the correct temperature b. Not working c. Missing the thermo wax in the heat sensor d. Contaminated with coolant
6. A defective thermostat can cause the powertrain control module to set what diagnostic trouble code (DTC)? a. P0171 b. P0172 c. P0128 d. P0300 7. A replacement plastic intake manifold may have a different design or appearance from the original factory-installed part. a. True b. False
3. Coolant drained from the cooling system when replacing a thermostat or water pump should be ______________. a. Reused b. Disposed of properly or recycled c. Filtered and reinstalled after the repair d. Poured down a toilet
8. The torque specifications for many plastic intake manifolds are in what unit? a. Pound-inches b. Pound-feet c. Ft-lb per minute d. Lb-ft per second
4. A water pump can fail to provide the proper amount of flow of coolant through the cooling system if what has happened? a. The coolant is leaking from the weep hole. b. The bearing is noisy. c. The impeller blades are worn or slipping on the shaft. d. A bearing failure has caused the shaft to become loose.
9. When replacing a timing belt, many experts and vehicle manufacturers recommend that what other part(s) should be replaced? a. Tensioner assembly b. Water pump c. Camshaft oil seal(s) d. All of the above
5. Intake manifold gaskets on a V-type engine can fail due to what factor? a. Fretting b. Coolant damage c. Relative movement between the intake manifold and the cylinder head d. All of the above
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10. Hybrid electric vehicles usually require special engine oil of what viscosity? a. SAE 5W-30 b. SAE 10W-30 c. SAE 0W-20 d. SAE 5W-40
ENGINE REMOVAL AND DISASSEMBLY
OBJECTIVES: After studying Chapter 28, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content areas “B” (Cylinder Head and Valve Train Diagnosis and Repair) and “C” (Engine Block Diagnosis and Repair). • Explain the differences between a long block and a short block assembly. • Describe how to remove an engine from a vehicle. • Explain how to remove engine accessory components, such as the covers and valve train components. • Discuss how to remove cylinder heads without causing warpage. • List the steps necessary to remove a piston from a cylinder. • Explain how to remove a valve from a cylinder head. KEY TERMS: Freshening 262 • Long block 262 • Rebuilding 262 • Short block 262 • Vibration damper 267
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FIGURE 28–1 A worn timing sprocket that resulted in a retarded valve timing and reduced engine performance.
FIGURE 28–2 A crate engine from Chrysler to be used in a restored muscle car. Using a complete new engine costs more than rebuilding an existing engine, but it has a warranty and uses all new parts.
ENGINE REPAIR OPTIONS TECHNICIAN AND OWNER DECISION The decision to repair an engine should be based on all the information about the engine that is available to the service technician and the vehicle owner.
In some cases, the engine might not be worth repairing. It is the responsibility of the technician to discuss the advantages and disadvantages of the different repair options with the customer.
The customer, who is paying for the repair, must make the final decision on the reconditioning procedure to be used. The repair might involve replacing a worn component instead of reconditioning. The decision will be based on the recommendation of the service technician.
taken out. The customer should be informed about any other engine problem, in order to authorize the service that the engine requires. In the high-performance industry, this procedure is called freshening the engine.
Major overhaul. A complete engine reconditioning job is called rebuilding. Sometimes, this type of reconditioning is called a major overhaul. To rebuild the engine, the engine must be removed from the chassis and be completely disassembled. All serviceable parts are reconditioned to either new or service standards. All bearings, gaskets, and seals are replaced. When the reconditioning is done properly, a rebuilt engine should operate like a new engine.
Short block. The quickest way to get a vehicle back in service is to exchange the faulty engine for a different one. In an older vehicle, the engine may be replaced with a used engine from a salvage yard. In some cases, only a reconditioned block, including the crankshaft, rods, and pistons, is used. This replacement assembly is called a short block. The original heads, valve train, oil pump, and all external components are reconditioned and used on the short block.
Long block. The replacement assembly is called a long block when the reconditioned assembly includes the heads and valve train. Many automotive machine shops maintain a stock of short and long blocks of popular engines. Usually, the original engine parts, called the core, are exchanged for the reconditioned assembly. The core parts are reconditioned by the automotive machine shop and put back in stock for the next customer.
Crate engines. Crate engines are new engines built by the engine manufacturer and sold through vehicle dealers. SEE FIGURE 28–2.
Remanufactured engines. Some engines are remanufactured and can be replaced in a day or two, greatly reducing the amount of time the customer is without a vehicle. The engine cores are completely disassembled, and each serviceable part is reconditioned with specialized machinery. Engines are then assembled on an engine assembly line similar to the original manufacturer’s assembly line. The parts that are assembled together as an engine have not come out of the same engine. The remanufactured engine usually has new pistons, valves, and lifters, together with other parts that are normally replaced in a rebuilt engine. All clearances and fits in the remanufactured
REPAIR OPTIONS
Most customers want to spend the least amount of money possible, so they have only the faulty component repaired. This is the correct procedure in many cases. Examples of component repairs include:
Component replacement. Timing chain replacement is an example of a component repair due to wear that can cause a loss of engine performance. If testing indicates that the timing chain has excessive slack, the front of the engine can be disassembled and the actual slack measured. Usually a slack of 0.5 in. (13 mm) or more indicates that the timing chain and gears need to be replaced. SEE FIGURE 28–1. Valve job. Valve leakage is corrected by doing a valve job. This does not necessarily correct the customer’s concerns, however. Stopping valve leakage improves manifold vacuum. After completing a valve job, the greater manifold vacuum may draw the oil past worn piston rings and into the combustion chamber during the intake stroke, causing oil consumption to increase. Minor overhaul. A minor overhaul can usually be done without removing the engine from the chassis. It requires removal of both the head and the oil pan. The overhaul is usually done when the engine lacks power, has poor fuel economy, uses an excessive amount of oil, produces visible tailpipe emissions, runs rough, or is hard to start. It is still only a repair procedure. Parts normally replaced include the piston rings, rod bearings and gaskets, as well as a valve job. Other engine problems may be noticed after the oil pan is removed and the piston and rod assemblies are
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engine are the same as in a new engine. A remanufactured engine should give service as good as that of a new engine, and it will cost about half as much. Remanufactured engines usually carry a warranty. This means that they will be replaced if they fail during the period of the warranty. They may even cost less than a rebuilt engine, because much of the reconditioning is done by specialized machines rather than by expensive skilled labor.
TECH TIP A Picture Is Worth a Thousand Words Take pictures with a cell phone camera, digital camera, or a video camcorder of the engine being serviced. These pictures will be worth their weight in gold when it comes time to reassemble or reinstall the engine. It is very difficult for anyone to remember the exact location of every bracket, wire, and hose. Referring back to the photos of the engine before work was started will help you restore the vehicle to like-new condition.
ENGINE REMOVAL CHECK SERVICE INFORMATION
Whenever any enginerelated work is being performed, always print out the specified procedure as published in service information to avoid doing any harm to the vehicle or the engine.
USUAL ENGINE REMOVAL PROCEDURES
Drain the engine oil. Draining the engine oil and removing the oil filter also helps prevent fluid loss during the removal process.
Disconnect fuel lines. Disconnect and plug all fuel supply and return lines.
Disconnect wiring and vacuum hoses. Mark and remove all vacuum hoses and electrical wiring attached to the engine.
The procedures
that are usually specified include:
Remove the hood. Removing the hood allows easier access to all of the components around the engine. Store the hood in a place where it will not be damaged. Some technicians place a fender cover on the roof of the vehicle and then place the hood upside down on top of the fender cover. Clean the engine area. The engine exterior and the engine compartment should be cleaned before work is begun. Using a power washer is the most commonly used way to clean the engine compartment area. A clean engine is easier to work on, and the cleaning not only helps to keep dirt out of the engine, but also minimizes accidental damage from slipping tools.
Disconnect the negative (⫺) battery cable, and remove the battery from the vehicle if it could interfere with the removal of the engine.
Remove the air cleaner assembly. Remove the hoses and other components of the air intake system. Mark or bag and tag all fasteners.
Remove all accessories. Those that usually need to be removed include the alternator, engine driven fan, and AIR pump, if equipped.
Drain the coolant. Draining coolant from the radiator and the engine block help reduce the chance of coolant getting into the cylinders when the cylinder head is removed. Dispose of the used coolant properly.
Remove the radiator. Disconnect the transmission oil cooler lines and radiator hoses from the radiator. Removing the radiator helps provide room for moving the engine during removal and helps prevent the possibility of damage.
Disconnect the exhaust system. On some engines, it may be easier to remove the exhaust manifold(s) from the cylinder head(s), whereas on others, it may be easier to disconnect the exhaust pipe from the manifold(s).
Recover the air-conditioning refrigerant. Set the airconditioning compressor aside and do not open the system unless absolutely necessary. If the air-conditioning system has to be opened to remove components, then the system must be evacuated. Tape or cover all open refrigerant fittings and hoses to prevent contaminants from entering the A/C system. Check service information for the exact procedures to follow.
Remove the power steering pump. Remove the fasteners to the power steering pump and set aside the pump and hoses.
PROCEDURE FOR ENGINE REMOVAL
There are two ways
to remove the engine. 1. The engine can be lifted out of the chassis with the transmission/transaxle attached. 2. The transmission/transaxle can be separated from the engine and left in the chassis. The method to be used must be determined before the engine is removed from the vehicle.
Rear-wheel-drive vehicle. The removal procedure for most rear-wheel-drive vehicles includes the following steps. STEP 1 Under the vehicle, remove the driveshaft (propeller shaft) and disconnect the exhaust pipes. Also remove the engine (motor) mounts. In some installations, it may be necessary to loosen the steering linkage idler arm to give clearance. The transmission controls and wiring need to be disconnected at the connectors, and clutch linkages disconnected and labeled. STEP 2 Attach a sling, either a chain or lift cable, to one of the following: • Factory-installed lifting hooks • Intake manifold • Cylinder head bolts, on top of the engine An engine lift hoist chain or cable is attached and snugged to take most of the weight. This leaves the engine resting on the mounts. NOTE: For the best results, use the factoryinstalled lifting hooks that are attached to the engine. These hooks are used in the assembly plant to install the engine and are usually in the best location to remove the engine. STEP 3 Remove the rear cross-member, and lower the transmission. Cover the extension housing with a plug or a plastic bag to help prevent the automatic transmission fluid from leaking during the removal process. If the engine alone is being removed, the transmission retaining bolts and torque converter fasteners will need to be removed. Check service information for exact procedures to follow when removing an automatic transmission.
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FIGURE 28–3 An engine must be tipped as it is pulled from the chassis.
RACK AND PINION STEERING GEAR CRADLE
FIGURE 28–5 The entire cradle, which included the engine, transaxle, and steering gear, was removed and placed onto a stand. The rear cylinder head has been removed to check for the root cause of a coolant leak. TECH TIP Tag and Bag
FIGURE 28–4 When removing just the engine from a front-wheeldrive vehicle, the transaxle must be supported. Shown here is a typical fixture that can be used to hold the engine if the transaxle is removed or to hold the transaxle if the engine is removed. STEP 4 The front of the engine must come almost straight up as the transmission slides from under the floor pan. The engine and transmission are hoisted free of the automobile, swung clear, and lowered on an open floor area. SEE FIGURE 28–3.
Front-wheel-drive vehicle. Check service information for the exact procedure to follow to remove the engine from a frontwheel-drive vehicle. Depending on the vehicle, the engine could be removed from the top or lowered and removed from underneath on many front-wheel-drive vehicles. Typical steps include: STEP 1 Disconnect units that might interfere with engine removal, including the steering unit, engine electrical harness, and radiator. STEP 2 If removing the engine from underneath, the upper strut and lower engine cradle fasteners will have to be removed. STEP 3 Disconnect the torque converter and bell housing bolts and clutch linkage if required. STEP 4 Often special holding fixtures are required to help hold the transaxle in place while removing the engine. SEE FIGURES 28–4 AND 28–5.
All components and fasteners should be marked for future reference. Large components should be marked or a tag installed that identifies the part. Smaller parts and fasteners should be placed in plastic bags and labeled as to what they are used for, such as the water pump bolts.
Always use at least four grade 8 bolts when mounting an engine to an engine stand. Using low-quality nongraded bolts or fewer than four bolts can cause the engine to fall. Also check to ensure that the proper threads of bolts are being used. Some engines use fractional threads, whereas others use metric threads.
Install the bolts so that at least 1/2 in. (13 mm) of thread is engaged in the back of the engine to ensure that the fasteners are securely attached the engine block.
Check that the engine is properly balanced on the engine stand before work is started on the engine. SEE FIGURE 28–6.
DISASSEMBLING A CAM-IN-BLOCK (OHV) ENGINE Check service information for the specified engine disassembly procedure. Read, understand, and follow all safety instructions. Following are the usual steps involved. STEP 1
Engines should be cold before disassembly to minimize the chance of warpage of the components that are being removed.
STEP 2
Removal of the rocker arm covers gives the first opportunity to see inside a part of the engine. Examine the rocker arms, valve springs, and valve tips for obvious defects. Remove the rocker arms and pushrods and, if they are to be reused, place them in a location so that the rockers and the pushrods can be installed back to their original location. SEE FIGURE 28–7.
STEP 3
Remove the intake manifold bolts and lift off the manifold. Use care to avoid damaging the parting surface as the gasket is loosened. When the intake manifold and lifter valley cover
ENGINE DISASSEMBLY MOUNTING THE ENGINE ON A STAND Engines should be installed to a sturdy engine stand. For safety, always check the following:
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FIGURE 28–6 Always use graded bolts—either grade 5 or 8 bolts—whenever mounting an engine to a stand.
FIGURE 28–8 Sometimes after the cylinder head has been removed, the engine condition is discovered to be so major that the entire engine may need to be replaced rather than overhauled. TECH TIP Disassembly Is the Reverse Order of Assembly Cylinder heads often warp upward in the center. Loosening the center head bolts first will tend to increase the warpage, especially if the head is being removed to replace a head gasket because of overheating. Always follow the torque table backwards, starting with the highest-number bolt and working toward the lowest number. In other words, always loosen fasteners starting at the end or outside of the component and work toward the inside or center of the component.
• A normal combustion chamber is coated with a layer of hard, light-colored deposits. • If the combustion chamber has been running too hot, the deposits will be very thin and white.
FIGURE 28–7 Keeping the pushrods and the lifters sorted by cylinder, including the spark plugs, is a wise way to proceed when disassembling the cylinder heads.
OVERHEAD CAMSHAFT (OHC) ENGINE DISASSEMBLY (if equipped) are off of V-type engines, the technician has another opportunity to examine the interior of the engine. On some V-type engines, it is possible to see the condition of the cam at the bottom of the lifter valley. STEP 4
The lifters can be removed at this time if they are causing the problem or if the engine valve train is to be serviced.
STEP 5
Remove the cylinder head bolts (also called cap screws) following the reverse of the installation procedure. Loosening the fasteners at the ends of the cylinder head first, then working toward the center, helps reduce the chance of warpage to the cylinder head. Be sure to notice and mark the head bolt locations as they are often different lengths depending on their location in the head. Carefully lift the head from the block deck. If the head gasket is stuck, carefully pry the head to loosen the gasket. Use care not to scratch the block or head machined surfaces. The combustion chamber in the head and the top of the piston should be given a thorough visual examination. SEE FIGURE 28–8. • Check the cylinder head and head gasket for signs of leakage.
Disassembling an overhead camshaft engine differs from a camin-block (OHV) engine. Check service information for the specified disassembly procedure for the engine being serviced. Read, understand, and follow all safety notices and warnings included in the instructions to help avoid causing damage to parts or components during the disassembly process. The usual steps include: STEP 1
Remove the intake and exhaust manifolds if they have not already been removed and bag and tag all fasteners.
STEP 2
Remove the crankshaft harmonic balancer pulley that will allow access to the timing chain or belt cover.
STEP 3
Remove the timing belt/chain cover(s) and then the timing belt(s) or chain(s).
STEP 4
With most overhead camshaft engines, the camshaft(s) must be removed before removing the cylinder head due to location of the head bolts.
STEP 5
Remove the cylinder head by removing the cylinder head bolts in the opposite order of assembly. This means to loosen the outermost fasteners first, then work toward the center of the cylinder head.
STEP 6
Carefully lift the cylinder head from the block.
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CYLINDER RIDGE NUMBERS STAMPED ON CONNECTING ROD AND ROD CAP
.009" WEAR UPPER END OF TOP RING TRAVEL .0003" WEAR UPPER END OF PISTON SKIRT TRAVEL
LOWER END OF BOTTOM RING TRAVEL
FIGURE 28–9 These connecting rods were numbered from the factory. If they are not, then they should be marked.
AREA OF GREATEST WEAR
PISTON SKIRT TRAVELS IN AREA OF LEAST WEAR
FIGURE 28–10 Most of the cylinder wear is on the top inch just below the cylinder ridge. This wear is due to the heat and combustion pressures that occur when the piston is near the top of the cylinder.
DISASSEMBLY OF THE SHORT BLOCK REMOVING THE OIL PAN
To remove the oil pan, turn the
engine upside down. NOTE: Some engine builders prefer to remove the oil pan before turning it upside down so the technician can see the oil pan deposits first. Deposits are a good indication of the condition and care taken of the engine. Heavy sludge indicates infrequent oil changes; hard carbon indicates overheating. The oil pump pickup screen should be checked to see how much plugging exists.
MARKING CONNECTING RODS AND CAPS The connecting rod caps should be marked (numbered) so that they can be reassembled in exactly the same position. If the connecting rods are not marked from the factory, then they should be marked using a number stamp, electric pencil, or permanent marker. SEE FIGURE 28–9. CAUTION: Some vehicle manufacturers warn not to use a punch or an electric pencil on powdered metal connection rods. Use only a permanent marker to label powdered metal rods. If in doubt as to the type of rod that is in the engine, use a marker to be safe.
REMOVING THE CYLINDER RIDGE
Before the pistons can be removed from the block, the ridge must be removed. Piston wear against the cylinder wall leaves an upper ridge, because the top ring does not travel all the way to the top of the cylinder. Ridge removal is necessary to avoid catching a ring on the ridge and breaking the piston. SEE FIGURE 28–10. The ridge is removed with a cutting tool that has a guide to help prevent accidental cutting below the ridge. SEE FIGURE 28–11.
FIGURE 28–11 This ridge is being removed with one type of ridge reamer before the piston assemblies are removed from the engine.
TECH TIP Measure the Cylinder Bore Before Further Disassembly As soon as the cylinder head has been removed from the engine, take a measurement of the cylinder bore. This is done for the following reasons. • To verify that the engine size is the same as specified by the vehicle identification number (VIN) • To measure the bore and compare it to factory specifications, to help the technician determine if the cylinder(s) are too worn to use or cannot be restored
STEP 2
Remove connecting rod nuts from the rod so that the rod cap with its bearing half can be removed.
STEP 3
Fit the rod bolts with protectors to keep the bolt threads from damaging the crankshaft journals, and then carefully remove the piston and rod assemblies.
STEP 4
After removal of each piston, replace the rod cap and nuts to avoid losing or mismatching them.
PISTON REMOVAL
Removing the piston and rod assembly includes the following steps. STEP 1
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Rotate the engine until the piston that is to be removed is at bottom dead center (BDC).
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FIGURE 28–12 Puller being used to pull the vibration damper from the crankshaft.
ROTATING ENGINE ASSEMBLIES REMOVAL HARMONIC BALANCER REMOVAL The next step after the water pump has been removed is to remove the crankshaft vibration damper (also called a harmonic balancer). The bolt and washer that hold the damper are removed. The damper should be removed only with a threaded puller. SEE FIGURE 28–12. If a hook-type puller is used around the edge of the damper, it may pull the damper ring from the hub. If this happens, the damper assembly will have to be replaced with a new assembly. With the damper assembly off, the timing cover can be removed, exposing the timing gear or timing chain. Examine these parts for excessive wear and looseness. SEE FIGURE 28–13. Bolted cam sprockets can be removed to free the timing chain. On some engines this will require removal of the crankshaft gear at the same time. Pressed-on gears and sprockets are removed from the shaft only if they are faulty. They are removed after the camshaft is removed from the block. It is necessary to remove the camshaft thrust plate retaining screws when they are used. CAMSHAFT REMOVAL The camshaft and balance shafts, if equipped, can be removed at this time, or they can be removed after the crankshaft is out. For best results, insert a long bolt into one of the camshaft threaded holes to serve as handles for removing (or installing) a camshaft. It must be carefully eased from the engine to avoid damaging the cam bearings or cam lobes. This is done most easily with the front of the engine pointing up. Bearing surfaces are soft and scratch easily, and the cam lobes are hard and can chip easily. CRANKSHAFT AND MAIN BEARING REMOVAL
The main bearing caps should be checked for position markings before they are removed. If they are not marked, use steel number stamps to mark them and also be sure to indicate which side of each main cap faces to the front of the engine. SEE FIGURE 28–14. They have been machined in place and will not fit perfectly in any other location. After marking, they can be removed to free the crankshaft. When the crankshaft is removed, the main bearing caps and bearings are reinstalled on the block to reduce the chance of damage to the caps.
FIGURE 28–13 When the timing chain cover was removed, the broken timing gear explained why this GM 4.3 liter V-6 engine stopped running.
ARROW ON MAIN BEARING CAP INDICATING TOWARD FRONT OF ENGINE
FIGURE 28–14 Most engines such as this Chevrolet V-8 with four-bolt main bearing caps have arrows marked on the bearing caps which should point to the front of the engine.
BLOCK INSPECTION After the pistons and crankshaft have been removed, then remove all cups and plugs and carefully inspect the block for faults that could affect whether the engine can be rebuilt. SEE FIGURE 28–15. Further detailed inspection should be completed after the components have been cleaned.
CYLINDER HEAD DISASSEMBLY OHV ENGINE CYLINDER HEADS
After the heads are removed and placed on the bench, the valves can be removed.
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VALVE SPRING COMPRESSOR
VALVE KEEPERS
FIGURE 28–15 This small block Chevrolet V-8 had water standing in the cylinders, causing a lot of rust, which was discovered as soon as the head was removed.
PARAFFIN WAX
FIGURE 28–17 A valve spring compressor is used to compress the valve spring before removing the keepers (locks). TECH TIP Mark It to Be Safe Whenever you disassemble anything, it is always wise to mark the location of parts, bolts, hoses, and other items that could be incorrectly assembled. Remember, the first part removed will be the last part that is assembled. If you think you will remember where everything goes—forget it! It just does not happen in the real world. One popular trick is to use correction fluid to mark the location of parts before they are removed. Most of these products are alcohol or water based, dry quickly, and usually contain a brush in the cap for easy use.
To disassemble a cylinder head, perform the following steps. FIGURE 28–16 A torch is used to heat gallery plugs. Paraffin wax is then applied and allowed to flow around the threads. This procedure results in easier removal of the plugs and other threaded fasteners that cannot otherwise be loosened.
TECH TIP The Wax Trick Before the engine block can be thoroughly cleaned, all oil gallery plugs must be removed. A popular trick of the trade for plug removal involves heating the plug (not the surrounding metal) with an oxyacetylene torch. The heat tends to expand the plug and make it tighter in the block. Do not overheat. As the plug is cooling, touch the plug with paraffin wax (beeswax or candle wax may be used). SEE FIGURE 28–16. The wax will be drawn down around the threads of the plug by capillary attraction as the plug cools and contracts. After being allowed to cool, the plug is easily removed.
STEP 1
Tap the valve spring retainer with a brass hammer, hitting the retainer on an angle to “break the taper” of the valve keepers (locks).
STEP 2
Using a valve spring compressor, compress the valve spring far enough to expose the keepers. SEE FIGURE 28–17.
STEP 3
Remove the two keepers using a magnet.
STEP 4
After the valve keepers have been removed, slowly release the compressor to remove and to free the valve retainer and spring.
STEP 5
The valve tip edge and keeper (lock) area should be lightly filed or stoned to remove any burrs before sliding the valve from the head. Burrs will scratch the valve guide.
STEP 6
Remove all valve stem seals and the metal spring seats that are used on aluminum heads.
STEP 7
When all valves are removed following the same procedure, carefully inspect the valve springs, retainers, keepers (locks), guides, and seats.
OHC ENGINE CYLINDER HEADS CAUTION: Always wear safety glasses when working on a cylinder head. Valve springs can release quickly, causing valve parts to fly.
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After the heads are removed and placed on the bench, the valves can be removed after the camshaft is removed. Often a special valve spring compressor is required to reach the valve retainers. Always read, understand, and follow all vehicle manufacturer’s instructions.
ENGINE REMOVAL
1
Before beginning work on removing the engine, mark and remove the hood and place it in a safe location.
3
Drain the coolant and dispose of properly.
5
Remove the accessory drive belt(s) and set the alternator, power steering pump, and airconditioning compressor aside.
2
For safety, remove the negative battery cable to avoid any possible electrical problems from occurring.
4
Disconnect all cooling system and heater hoses and remove the radiator.
6
Remove the air intake system including the air filter housing as needed.
CONTINUED
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ENGINE REMOVAL
(CONTINUED)
7
Remove the electrical connector from all sensors and label.
8
9
Safely hoist the vehicle and disconnect the exhaust system from the exhaust manifolds.
10
Mark and then remove the fasteners connecting the flex plate to the torque converter.
12
Secure the lifting chain to the engine hooks and carefully remove the engine from the vehicle.
11 270
Lower the vehicle and remove the engine mount bolts and transaxle bell housing fasteners.
CHAPTER 28
Disconnect the engine wiring harness connector at the bulkhead.
REVIEW QUESTIONS 2. When should the factory-installed lifting hooks be used?
1. What are the differences between a minor and a major overhaul?
4. State two reasons for the removal of the ridge at the top of the cylinder.
3. Why should the cylinder bore be measured before continuing with an engine disassembly?
5. Explain why the burrs must be removed from valves before removing the valves from the cylinder head.
CHAPTER QUIZ 1. A short block includes the ______________. a. Block b. Crankshaft and main bearings c. Pistons, rods, and rod bearings d. All of the above 2. When removing cylinder heads, the fasteners should be removed in which order? a. The reverse order of tightening b. The same order as the specified tightening sequence c. Any order d. Loosened slightly in the same order as the tightening sequence and then removed in any order 3. A long block can be made from a short block with the addition of ______________. a. Cylinder heads and valve train b. Intake and exhaust manifolds c. Oil pump, oil pan, and timing chain cover d. Fuel pump, carburetor, and air cleaner assembly 4. What needs to be removed before the valves can be removed from the cylinder head? a. The valve keepers b. The camshaft if OHV engine c. The cylinder head from the block d. Both a and c 5. With the rocker cover (valve cover) removed, the technician can inspect all items except ______________. a. Combustion chamber deposits b. Rocker arms and valve spring c. Camshaft (overhead camshaft engine only) d. Valve stems and pushrods (overhead valve engines only)
7. The ridge at the top of the cylinder ______________. a. Is caused by the rings that do not travel all the way to top of the cylinder b. Represents a failure of the top piston ring to correctly seal against the cylinder wall c. Should not be removed before removing pistons except when reboring the cylinders d. Means that a crankshaft with an incorrect stroke was installed in the engine 8. Before the timing chain can be inspected and removed, the ______________ must be removed. a. Valve cover b. Vibration damper c. Cylinder head(s) d. Intake manifold (V-type engines only) 9. Before the valves are removed from the cylinder head, what operations need to be completed? a. Remove valve keepers (locks) b. Remove cylinder head(s) from the engine c. Remove burrs from the stem of the valve(s) d. All of the above 10. Technician A says that a minor overhaul can often be done with the engine remaining in the vehicle. Technician B says that a core is required for most remanufactured engines. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
6. After the oil pan (sump) is removed, the technician should inspect ______________. a. The oil pump and pickup screen b. To make certain that all rod and main bearings are numbered or marked c. The valve lifters (tappets) for wear d. Both a and b
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chapter
29
ENGINE CLEANING AND CRACK DETECTION
OBJECTIVES: After studying Chapter 29, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “A” (General Engine Diagnosis). • List the types of engine cleaning methods. • List the various methods that can be used to check engine parts for cracks. • Describe crack repair procedures. KEY TERMS: Acid materials 273 • Agitation 275 • Aqueous-based solutions 274 • Caustic materials 273 • Fusible link 275 • Hydroseal 275 • pH 273 • Putty knife 272 • Pyrolytic 274 • Ultrasonic cleaning 275 • Zyglo 276
INTRODUCTION After an engine has been disassembled and before it can be overhauled or repaired, the engine and engine parts should go through two important operations. 1. All parts, including fasteners, must be thoroughly cleaned. 2. All components and parts must be inspected to ensure that they are serviceable and free from faults such as cracks.
MECHANICAL CLEANING PRINCIPLES
Heavy deposits should be removed by mechanical cleaning before using other cleaning methods. Mechanical cleaning involves:
Scraping
Abrasive brushing
Abrasive blasting
FIGURE 29–1 An air-powered grinder attached to a bristle pad being used to clean the gasket surface of a cylinder head. This type of cleaning pad should not be used on the engine block where the grit could get into the engine oil and cause harm when the engine is started and run after the repair.
TECH TIP
SCRAPING The scraper most frequently used is a putty knife, or a plastic card. The broad blade of the putty knife helps avoid scratching the surface as it is used to clean the parts. A plastic card such as an old gift, credit, or other similar card can be used to clean aluminum parts such as cylinder head gasket surfaces without causing any damage.
The Ice Scraper Trick Using a steel scraper can damage aluminum heads or block deck surfaces. To prevent damage, try using a file to sharpen a plastic ice scraper and then use this to scrape gaskets from aluminum engine parts. This method works very well.
ABRASIVE PADS OR DISCS
An abrasive pad or disc can be used on disassembled parts only. After an abrasive pad or disc has been used, the part must be thoroughly cleaned to remove the particles from the plastic bristles or pad. The abrasive aluminum oxide particles from the bristles can get into the engine and cause major damage. There are three colors of rotary discs, and each is made from a different grit size of abrasive. The three colors of bristle discs and their applications include:
White. Has the finest grit size, and is used for cleaning aluminum parts
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Yellow. Has a coarse grit, and can be used on aluminum
Green. For use on cast-iron components only
SEE FIGURES 29–1 AND 29–2. CAUTION: Do not use steel wire brushes on aluminum parts! Steel is harder than aluminum and will remove some of the aluminum from the surface during cleaning.
FIGURE 29–2 An abrasive disc commonly called by its trade name, Scotch Brite™ pad.
FIGURE 29–3 Using baking soda is the recommended way to clean engine parts because any soda that is left on or in the part is dissolved in oil or water, unlike either sand or glass beads, which can be engine damaging.
MEDIA BLASTING Media blasting with baking soda is the cleaning method of choice for most shops. Baking soda (bicarbonate of soda) works well because it is:
Nontoxic
Nonflammable
Nonhazardous
Environmentally safe
A soda blasting machine uses compressed air to deliver the baking soda media onto the part being cleaned. SEE FIGURE 29–3. Cleaning cast-iron or aluminum engine parts with solvents or heat usually requires another operation to achieve a uniform surface finish. Blasting the parts with steel, cast-iron, aluminum, or stainless steel shot, baking soda, or glass beads is a simple way to achieve a matte or satin surface finish on the engine parts. To keep the shot or beads from sticking to the parts, they must be dry, without a trace of oil or grease, prior to blasting. This means that blasting is the second cleaning method after the part has been precleaned in a tank, spray washer, or oven. Some blasting is done automatically in an airless shot-blasting machine. Another method is to hard-blast parts in a sealed cabinet. SEE FIGURE 29–4. CAUTION: Glass beads often remain in internal passages of engine parts, where they can come loose and travel through the cylinders when the engine is started. Among other places, these small but destructive beads can easily be trapped under the oil baffles of rocker covers and in oil pans and piston ring grooves. To help prevent the glass beads from sticking, be sure the parts being cleaned are free of grease and dirt, and completely dry.
CHEMICAL CLEANERS pH Most chemical cleaners used for cleaning carbon-type deposits are strong soaps called caustic materials. pH value, measured on a scale from 1 to 14, indicates the amount of chemical activity in the soap. The term pH is from the French pouvoir hydrogine, meaning “hydrogen power.” Pure water is neutral; on the pH scale, water is pH 7. Caustic materials have pH numbers from 8 through 14.
FIGURE 29–4 Small engine parts can be blasted clean in a sealed cabinet. The higher the number, the stronger the caustic action will be. Acid materials have pH numbers from 1 through 6. The lower the number, the stronger the acid action will be. Caustic materials and acid materials neutralize each other. This is what happens when baking soda (a caustic) is used to clean the outside of the battery (an acid surface). The caustic baking soda neutralizes any sulfuric acid that has been spilled or splashed on the outside of the battery. CAUTION: Whenever working with chemicals, you must use eye protection.
SOLVENT-BASED CLEANING Cleaning chemicals applied to engine parts will mix with and dissolve deposits. The chemicals loosen the deposits so that they can be brushed or rinsed from the surface. A deposit is said to be soluble when it can be dissolved with a chemical or solvent. Chemical cleaning can involve a spray washer or a soak in a cold or hot tank. The cleaning solution is usually solvent based, with a medium pH rating of between 10 and 12. Most chemical solutions also contain silicates to protect the metal (aluminum) against corrosion. Strong caustics do an excellent job on cast-iron items but are often too corrosive for aluminum parts. Aluminum cleaners include mineral spirit solvents as well as alkaline detergents.
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FIGURE 29–5 A pressure jet washer is similar to a large industrialsized dishwasher. Each part is then rinsed with water to remove chemicals or debris that may remain there while it is still in the tank.
CAUTION: When cleaning aluminum cylinder heads, blocks, or other engine components, make sure that the chemicals used are “aluminum safe.” Many chemicals that are not aluminum safe may turn the aluminum metal black. Try to explain that to a customer!
WATER-BASED CHEMICAL CLEANING Because of environmental concerns, most chemical cleaning is now performed using water-based solutions (also called aqueous-based solutions). Most aqueous-type chemicals are silicate based and are mixed with water. Aqueous-based solutions can be used in one of two ways.
Sprayed on
Used in a tank for soaking parts
Aluminum heads and blocks usually require overnight soaking in a solution kept at about 190°F (90°C). For best results, the cleaning solution should be agitated.
FIGURE 29–6 A microbial cleaning tank uses microbes to clean grease and oil from parts. is added to the steam and water to aid in the cleaning. This mixture is so active that it will damage and even remove paint, so painted surfaces must be protected from the spray. Engines are often steam cleaned before they are removed from the vehicle.
THERMAL CLEANING TEMPERATURES INVOLVED Thermal cleaning uses heat to vaporize and change dirt, oil, and grease into a dry, powdery ash. Thermal cleaning is best suited for cleaning cast iron, where temperatures as high as 800°F (425°C) are used, whereas aluminum should not be heated to over 600°F (315°C). ADVANTAGES
The major advantages of thermal cleaning include the following: 1. This process cleans the inside as well as the outside of the casting or part. 2. The waste generated is nonhazardous and is easy to dispose of. However, the heat in the oven usually discolors the metal, leaving it looking dull.
SPRAY AND STEAM WASHING SPRAY WASHING
A spray washer directs streams of liquid through numerous high-pressure nozzles to dislodge dirt and grime on an engine surface. The force of the liquid hitting the surface, combined with the chemical action of the cleaning solution, produces a clean surface. Spray washing is typically performed in an enclosed washer (like a dishwasher), where parts are rotated on a washer turntable. SEE FIGURE 29–5. Spray washing is faster than soaking. A typical washer cycle is less than 30 minutes per load, compared to eight or more hours for soaking. Most spray washers use an aqueous-based cleaning solution heated to 160°F to 180°F (70°C to 80°C) with foam suppressants. High-volume remanufacturers use industrial dishwashing machines to clean the disassembled engine component parts.
MICROBIAL CLEANING
Microbial cleaning uses microbes that are living organisms (single-celled bacteria) that literally “eat” the hydrocarbons (grease and oils) off of the parts being cleaned. The typical microbial cleaning system includes three parts.
A liquid assists the microbes by breaking the hydrocarbons to a smaller (molecular) size.
The microbes, stored in a dormant phase until ready for use, give an indefinite shelf life to the product. Once the microbes come into contact with the liquid, they wake up from the dormant state and begin to feed.
A third part is a blend of nutrients to ensure that the microbes start to multiply in the shortest amount of time to help speed the cleaning time needed.
Microbial cleaning is environmentally friendly, but is slower to clean parts. SEE FIGURE 29–6.
STEAM CLEANING
Steam vapor is mixed with high-pressure water and sprayed on the parts. The heat of the steam plus the force of the high-pressure water perform the actual cleaning. Steam cleaning must be used with extreme care. Usually, a caustic cleaner
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PYROLYTIC OVEN A pyrolytic (high-temperature) oven cleans engine parts by decomposing dirt, grease, and gaskets with heat in a manner similar to that of a self-cleaning oven. This method of engine
AIRLESS BLASTER
PYROLYTIC OVEN
(a)
FIGURE 29–8 An ultrasonic cleaner being used to clean fuel injectors.
pumps the cleaning solution over the parts. This movement, called agitation, keeps fresh cleaning solution moving past the soil to help it loosen. The parts washer is usually equipped with a safety cover held open by a low-temperature fusible link. If a fire occurs, the fusible link will melt and the cover will drop closed to snuff the fire out.
(b)
FIGURE 29–7 (a) A pyrolytic (high-temperature) oven cleans by baking the engine parts. After the parts have been cleaned, they are then placed into an airless blaster. This unit uses a paddle to scoop stainless steel shot from a reservoir and forces it against the engine part. The parts must be free of grease and oil to function correctly. (b) This cleaned engine block has been baked and shot blasted. parts cleaning is the least hazardous method and is becoming the most popular because there is no hazardous waste associated with it. Labor costs are also reduced because the operator does not need to be present during the actual cleaning operation. SEE FIGURE 29–7.
TANK AND VAPOR CLEANING COLD TANK CLEANING
The cold soak tank is used to remove grease and carbon. The disassembled parts are placed in the tank so that they are completely covered with the chemical cleaning solution. After a soaking period, the parts are removed and rinsed until the milky appearance of the emulsion is gone. The parts are then dried with compressed air. The clean, dry parts are then usually given a very light coating of clean oil to prevent rusting. Carburetor cleaner, purchased with a basket in a bucket, is one of the most common types of cold soak agents in the automotive shop. Usually, there will be a layer of water over the chemical to prevent evaporation of the chemical. This water layer is called a hydroseal. Parts washers are often used in place of soaking tanks. This equipment can move parts back and forth through the cleaning solution or
HOT TANK CLEANING The hot soak tank is used for cleaning heavy organic deposits and rust from iron and steel parts. The caustic cleaning solution used in the hot soak tank is heated to near 200°F (93°C) for rapid cleaning action. The solution must be inhibited when aluminum is to be cleaned. After the deposits have been loosened, the parts are removed from the tank and rinsed with hot water or steam cleaned, which dries them rapidly. They must then be given a light coating of oil to prevent rusting. HINT: Fogging oil from a spray can does an excellent job of coating metal parts to keep them from rusting.
VAPOR CLEANING Vapor cleaning is popular in some automotive service shops. The parts to be cleaned are suspended in hot vapors above a perchloroethylene solution. The vapors of the solution loosen the soil from the metal so that it can be blown, wiped, or rinsed from the surface.
ULTRASONIC AND VIBRATORY CLEANING ULTRASONIC CLEANING Ultrasonic cleaning is used to clean small parts that must be absolutely clean, such as hydraulic lifters and diesel injectors. The disassembled parts are placed in a tank of cleaning solution that is then vibrated at ultrasonic speeds to loosen all the soil from the parts. The soil goes into the solution or falls to the bottom of the tank. SEE FIGURE 29–8. VIBRATORY CLEANING
The vibratory method of cleaning is best suited for small parts. Parts are loaded into a vibrating bin with small odd-shaped ceramic or steel pieces, called media, with a cleaning solution of mineral spirits or water-based detergents that usually contain a lubricant additive to help the media pieces slide around more freely. The movement of the vibrating solution and the scrubbing action of the media do an excellent job of cleaning metal.
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S
N S
FIGURE 29–9 The top deck surface of a block is being tested using magnetic crack inspection equipment.
CRACK DETECTION VISUAL INSPECTION After the parts have been thoroughly cleaned, they should be reexamined for defects. A magnifying glass is helpful in finding defects. Internal parts such as pistons, connecting rods, and crankshafts that have cracks should be replaced. Cracks in the block and heads, however, can often be repaired.
N
FIGURE 29–10 If the lines of force are interrupted by a break (crack) in the casting, then two magnetic fields are created and the powder will lodge in the crack.
MAGNETIC CRACK DETECTION The process of detecting cracks using a magnetic field is commonly referred to by the brand name Magnafluxing. Cracks in engine blocks, cylinder heads, crankshafts, and other engine components are sometimes difficult to find during a normal visual inspection, which is why all remanufacturers and most engine builders use a crack detection procedure on critical engine parts. Magnetic flux testing is the method most often used on steel and iron components. A metal engine part (such as a cast-iron cylinder head) is connected to a large electromagnet. Magnetic lines of force are easily conducted through the iron part and concentrate on the edges of a crack. A fine iron powder is then applied to the part being tested, and the powder will be attracted to the strong magnetic concentration around the crack. SEE FIGURES 29–9 THROUGH 29–11. DYE-PENETRANT TESTING Dye-penetrant testing is often used on pistons and other parts constructed of aluminum or other nonmagnetic material. A dark red penetrating chemical is first sprayed on the component being tested. After cleaning, a white powder is sprayed over the test area. If a crack is present, the red dye will stain the white powder. Even though this method will also work on iron and steel (magnetic) parts, it is often used only on nonmagnetic parts because magnetic methods do not work on these parts. FLUORESCENT-PENETRANT TESTING
To be seen, fluorescent penetrant requires a black light. It can be used on iron, steel, or aluminum parts. Cracks show up as bright lines when viewed with a black light. The method is commonly called Zyglo, a trademark of the Magnaflux Corporation.
PRESSURE TESTING Cylinder heads and blocks are often pressure tested with air and checked for leaks. All coolant passages are blocked with rubber plugs or gaskets, and compressed air is applied to the water jacket(s). The head or block is then lowered into water, where air bubbles indicate a leak. For more accurate results, the water should be heated because the hot water expands the
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CRACK
FIGURE 29–11 This crack in a vintage Ford 289, V-8 block was likely caused by the technician using excessive force trying to remove the plug from the block. The technician should have used heat and wax, not only to make the job easier, but also to prevent damaging the block. casting by about the same amount as an operating engine would. An alternative method involves running heated water with a dye through the cylinder or block. Any leaks revealed by the dyed water indicate a crack. SEE FIGURES 29–12 AND 29–13.
CRACK REPAIR CRACK CONCERNS Cracks in the engine block can cause coolant to flow into the oil or oil into the coolant. A cracked block can also cause coolant to leak externally from a crack that goes through
CRACK IN CYLINDER WALL
SOAPY WATER SPRAY BOTTLE
FIGURE 29–12 To make sure that the mark observed in the cylinder wall was a crack, compressed air was forced into the water jacket while soapy water was sprayed on the cylinder wall. Bubbles confirmed that the mark was indeed a crack.
BUBBLES FROM CRACK IN CYLINDER HEAD
(a)
AIR HOSE
(b)
CYLINDER HEAD
FIGURE 29–13 A cylinder head is under water and being pressure tested using compressed air. Note that the air bubbles indicate a crack.
(c)
to a coolant passage. Cracks in the head will allow coolant to leak into the engine, or they will allow combustion gases to leak into the coolant. Cracks across the valve seat cause hot spots on the valve, which will burn the valve face. A head with a crack will either have to be replaced or the crack will have to be repaired.
STOP DRILLING A hole can be drilled at each end of the crack to keep it from extending farther, a step sometimes called stop drilling. Cracks that do not cross oil passages, bolt holes, or seal surfaces can sometimes be left alone if stopped. CRACK-WELDING CAST IRON
It takes a great deal of skill to weld cast iron. The cast iron does not puddle or flow as steel does when it is heated. Heavy cast parts, such as the head and block, conduct heat away from the weld so fast that it is difficult to get the part hot enough to melt the iron for welding. When it does melt, a crack will often develop next to the edge of the weld bead. Welding can be done satisfactorily when the entire cast part is heated red-hot. A new technique involves flame welding using a special torch. SEE FIGURE 29–14.
(d)
FIGURE 29–14 (a) Before welding, the crack is ground out using a carbide grinder. (b) Here the technician is practicing using the special cast-iron welding torch before welding the cracked cylinder head. (c) This is the finished welded crack before final machining. (d) Note the finished cylinder head after the crack has been repaired using welding.
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TAPERED PLUG
TAPERED REAMER
FIGURE 29–17 Screwing a tapered plug in the hole.
FIGURE 29–15 Reaming a hole for a tapered plug. HAMMER
TAPERED TAP
HACKSAW SLOT
FIGURE 29–18 Cutting the plug with a hacksaw. FIGURE 29–16 Tapping a tapered hole for a plug.
ORIGINAL CRACK
CRACK-WELDING ALUMINUM Cracks in aluminum can be welded using a Heli-arc® or similar welder that is specially designed to weld aluminum. The crack should be cut or burned out before welding begins. The old valve-seat insert should be removed if the crack is in or near the combustion chamber.
FIRST PLUG SECOND PLUG
CRACK PLUGGING
In the process of crack plugging, a crack is closed using interlocking tapered plugs. This procedure can be performed to repair cracks in both aluminum and cast-iron engine components. The ends of the crack are center punched and drilled with the proper size of tap drill for the plugs. The hole is reamed with a tapered reamer ( FIGURE 29–15) and is then tapped with a special tap to give full threads ( FIGURE 29–16). The plug is coated with sealer; then it is tightened into the hole ( FIGURE 29–17), sawed about one-fourth of the way through, and broken off. The saw slot controls the breaking point ( FIGURE 29–18). If the plug should break below the surface, it will have to be drilled out and a new plug installed. The plug should go to the full depth or thickness of the cast metal. After the first plug is installed on each end, a new hole is drilled with the tap drill so that it cuts into the edge of the first plug. This new hole is reamed
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PLUGS INTERLOCK
FIGURE 29–19 Interlocking plugs.
and tapped, and a plug is inserted as before. The plug should fit about one-fourth of the way into the first plug to lock it into place ( FIGURE 29–19). Interlocking plugs are placed along the entire crack, alternating slightly from side to side. The exposed ends of the plugs are peened over with a hammer to help secure them in place. The surface of the plugs is then ground or filed down nearly to the gasket surface. In the combustion chamber and at the ports, the plugs are ground down to the original surface using a hand grinder. The gasket surface of the head must be resurfaced after the crack has been repaired. SEE FIGURE 29–20 for an example of a cylinder head repair using plugs.
(a)
(b)
(c)
FIGURE 29–20 (a) A hole is drilled and tapped for the plugs. (b) The plugs are installed. (c) After final machining, the cylinder head can be returned to useful service.
REVIEW QUESTIONS 1. Describe five methods that could be used to clean engines or engine parts.
3. How can engine block and cylinder heads be repaired if cracked?
2. Explain magnetic crack inspection, dye-penetrant testing, and fluorescent-penetrant testing methods and where each can be used.
CHAPTER QUIZ 1. Abrasive pads or discs should be used ______________. a. On disassembled engine parts only b. According to the specified grit size for the material being cleaned c. But clean the part thoroughly to wash away the abrasive material d. All of the above 2. What actually does the cleaning when using steam? a. Heat from the steam b. Pressure behind the steam c. Abrasives used d. Both a and b
3. Aqueous-based cleaning means ______________. a. Water based b. Abrasive based c. Strong chemical based d. All of the above 4. A pyrolytic oven is used to clean parts; however, caution should be used to limit the temperature, to prevent damaging engine parts. What are the maximum recommended temperatures? a. 300°F (150°C) for all engine parts b. 600°F (315°C) for aluminum parts c. 800°F (425°C) for cast iron d. Both b and c
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5. Which media is best to use for cleaning parts as it does not need to be thoroughly cleaned after using? a. Baking soda c. Glass beads b. Stainless steel shot d. Aluminum shot 6. Cleaning chemicals are usually either a caustic material or an acid material. Which of the following statements is true? a. Both caustics and acids have a pH of 7 if rated according to distilled water. b. An acid is lower than 7 and a caustic is higher than 7 on the pH scale. c. An acid is higher than 7 and a caustic is lower than 7 on the pH scale. d. Pure water is a 1 and a strong acid is a 14 on the pH scale. 7. Many cleaning methods involve chemicals that are hazardous to use. The least hazardous method is generally considered to be the ______________. a. Pyrolytic oven c. Hot soak tank b. Hot vapor tank d. Cold soak tank
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8. Magnetic crack inspection ______________. a. Uses a red dye to detect cracks in aluminum b. Uses a black light to detect cracks in iron parts c. Uses a fine iron powder to detect cracks in iron parts d. Uses a magnet to remove cracks from iron parts 9. Technician A says that engine parts should be cleaned before a thorough test can be done to detect cracks. Technician B says that pressure testing can be used to find cracks in blocks or cylinder heads. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 10. Plugging can be used to repair cracks ______________. a. In cast-iron cylinder heads b. In aluminum cylinder heads c. In both cast-iron and aluminum cylinder heads d. Only in cast-iron blocks
CYLINDER HEAD AND VALVE GUIDE SERVICE
OBJECTIVES: After studying Chapter 30, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “B” (Cylinder Head and Valve Train Diagnosis and Repair). • Identify combustion chamber types. • List the steps necessary to recondition a cylinder head. • Describe how to inspect and measure valve guides. • Discuss valve guide repair options. KEY TERMS: Arithmetic average roughness height (RA) 287 • Bend 286 • Bronze guide liners 291 • Bronze guides 291 • Cam tunnel 286 • Cast-iron guides 291 • Concentric 289 • Crossflow head 281 • Distortion 286 • Fire deck 286 • Milling 287 • Oversize (OS) stems 290 • Port 283 • Porting (relieving) 284 • Quench area 281 • Root-mean-square (RMS) 287 • Siamese port 283 • Spark plug placement 281 • Spiral bronze alloy bushing 291 • Squish area 280 • Surface grinder 287 • Surface-tovolume ratio 281 • Thin-walled bronze alloy sleeve bushing 291 • Twist 286 • Unshrouding 284 • Valve duration 282 • Valve guide knurling 290 • Valve guides 289 • Valve seat inserts 289 • Valve shrouding 281 • Warpage 286
INTRODUCTION The repair and reconditioning of cylinder heads represents the most frequent engine repair operation of any engine component. The highest temperatures and pressures in the entire engine are located in the combustion chamber of the cylinder head. Its valves must open and close thousands of times when the engine is operated.
coolant, and sometimes engine oil. In an overhead camshaft design engine, the cylinder head also supports all of the valve train components including the camshaft, rocker arms, or followers, as well as the intake and exhaust valves and valve guides. SEE FIGURE 30–1.
DESIGN FEATURES Most cylinder head designs incorporate the following design factors to achieve fast burning of the air-fuel mixture and to reduce exhaust emissions. These factors include:
CYLINDER HEADS CONSTRUCTION Cylinder heads support the valves and valve train, and contain passages for the flow of intake, exhaust gases,
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Squish area. This is an area of the combustion chamber where the piston nearly contacts the cylinder head. When the piston is moving upward toward the cylinder head, the airfuel mixture is rapidly pushed out of the squish area, causing turbulence. Turbulence helps mix the air and fuel, thereby ensuring a more uniform and complete combustion. SEE FIGURE 30–2.
ROCKER ARM
CAMSHAFT
FIGURE 30–3 Locating the spark plug in the center of the combustion chamber reduces the distance the flame front must travel.
CYLINDER HEAD
VALVE SEAT INTAKE VALVE
VALVE GUIDE EXHAUST VALVE
FIGURE 30–1 The seats and guides for the valves are in the cylinder head as well as the camshaft and the entire valve train if it is an overhead camshaft design.
COOLANT PASSAGE
SPARK PLUG OPENING
FIGURE 30–4 The combustion chamber of the 5.7 liter Chrysler Hemi cylinder head shows the two spark plugs used to ensure rapid burn for best power and economy with the lowest possible exhaust emissions. chamber design, and valve placement. Some engines use two spark plugs per cylinder to achieve rapid combustion needed to meet exhaust emissions standards. SEE FIGURE 30–4 for an example of a two-spark plug combustion chamber used in a hemispherical (Hemi) cylinder head design.
SQUISH AREA
FIGURE 30–2 A wedge-shaped combustion chamber showing the squish area where the air-fuel mixture is squeezed, causing turbulence that pushes the mixture toward the spark plug.
Quench area. The squish area can also be the quench area where the air-fuel mixture is cooled by the cylinder head. The quench area is the flat area of the combustion chamber that is above the flat area of the piston. As the piston moves upward on the compression stroke, the air-fuel mixture is forced from this area as the piston gets near the top. The quench area operates at lower temperatures than the rest of the combustion chamber and can cause the gasoline vapors to condense on these cooler surfaces, thereby helping to reduce detonation caused by the autoignition of the end gases in the combustion chamber. Spark plug placement. The best spark plug placement is at the center of the combustion chamber. SEE FIGURE 30–3. The closer to the center, the shorter the flames travel to all edges of the combustion chamber, which also reduces abnormal combustion (ping or spark knock). While it is best to have the spark plug in the center, some combustion chamber designs do not allow this, due to valve size, combustion
Surface-to-volume ratio. This ratio is an important design consideration for combustion chambers. A typical surfaceto-volume ratio is 7.5:1, which means the surface area of the combustion chamber divided by the volume is 7.5. If the ratio is too high, there is a lot of surface area where fuel can adhere, causing an increase in unburned hydrocarbon (HC) emissions. The cool cylinder head causes some of the air-fuel mixture to condense, resulting in a layer of liquid fuel on the surfaces of the combustion chamber. This layer of condensed fuel will not burn because it is not surrounded by oxygen needed for combustion. As a result, this unburned fuel is pushed out of the cylinder by the piston on the exhaust stroke.
Valve shrouding. Shrouding means that the valve is kept close to the walls of the combustion chamber to help increase mixture turbulence. Although shrouding the intake valve can help swirl and increase turbulence, it also reduces the flow into the engine at higher engine speeds. SEE FIGURE 30–5.
Crossflow valve placement. Valve placement in the cylinder head is an important factor in breather efficiency. By placing the intake and the exhaust valves on the opposite sides of the combustion chamber, an easy path from the intake port through the combustion chamber to the exhaust port is provided. This is called a crossflow head design. SEE FIGURE 30–6.
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INTAKE VALVE (OPEN)
EXHAUST VALVE (CLOSED)
OPEN VALVE
LIFT
2”
½”
DISTANCE AROUND (3.1416 × DIA.) VALVE SEAT OPENING AREA = DISTANCE × LIFT
FIGURE 30–7 Method for measuring the valve opening space.
?
SPARK PLUG
FREQUENTLY ASKED QUESTION
What Is Carbon Knock? SHROUDED AREA
SHROUD-TO-VALVE CLEARANCE
FIGURE 30–5 The shrouded area around the intake valve causes the intake mixture to swirl as it enters the combustion chamber.
T
S AU
H EX
E
AK INT
FIGURE 30–6 A typical cross flow cylinder head design, where the flow into and out of the combustion chamber is from opposite sides of the cylinder head.
COMBUSTION CHAMBER DESIGNS
Combustion chamber shape has an effect on engine power and efficiency. The combustion chamber is created as two parts.
The upper part consists of the cylinder head and cylinder walls.
The lower part is the top of the piston. The most commonly used combustion chamber shapes include:
Wedge. Commonly found on many two-valve pushrod engines (cam-in-block) designs
Pentroof. Commonly found on many four-valve overhead camshaft design engines
Hemi. Found on both cam-in-block and overhead camshaft design engines
FOUR-VALVE CYLINDER HEADS
Adding more than two valves per cylinder permits more gas to flow into and out of the engine with greater velocity without excessive valve duration. Valve
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Carbon knock was a common occurrence in older engines that were equipped with carburetors and high compression ratios. As carburetors aged, the mixture would tend to be richer than normal, due to a leaking needle and seat, as well as a fuel-saturated float. This richer mixture would often cause carbon deposits to form in the combustion chamber. During light load conditions when the spark advance was greatest, a spark knock would occur, caused by a higher compression ratio due to the carbon deposits. This knocking was often very loud, sounding like a rod bearing noise, because in some cases the carbon deposits actually caused physical contact between the piston and the carbon. Many engines were disassembled in the belief that the cause of the knocking sound was a bearing, only to discover that the bearings were okay. Carbon knock can still occur in newer engines, especially if there is a fault in the fuel system that would allow a much richer-than-normal air-fuel mixture, causing excessive carbon deposits to form in the combustion chamber. Often a decarbonization using chemicals will correct the knocking.
duration is the number of degrees by which the crankshaft rotates when the valve is off the valve seat. Increased valve duration increases valve overlap. The valve overlap occurs when both valves are open at the same time at the end of the exhaust stroke and at the beginning of the intake stroke. At lower engine speeds, the gases can move back and forth between the open valves. Therefore, the greater valve duration hurts low engine speed performance and driveability, but it allows for more air-fuel mixture to enter the engine for better high-speed power. The maximum amount of gas moving through the opening area of a valve depends on the distance around the valve and the degree to which it lifts open. SEE FIGURE 30–7. Using normal opening lift of about 25% of the valve head diameter as an example, if the intake valve is 2 in. diameter, the normal amount of lift off the seat (not cam lobe height) is 25% of 2 in., or 1/2 (0.5) in. However, the amount of air-fuel mixture that can enter a cylinder depends on the total area around the valve, not just the amount of lift. The distance around a valve is calculated by the equation: pi ⴛ D or 3.1416 ⴛ Valve diameter
SEE FIGURE 30–8.
DISTANCE AROUND 1 7/16" INTAKE VALVE = 4.52"
EXHAUST VALVES
INTAKE VALVES
FIGURE 30–9 Typical four-valve head. The total area of opening of two small intake valves and two smaller exhaust valves is greater than the area of a two-valve head using much larger valves. The smaller valves also permit the use of smaller intake runners for better low-speed engine response.
DISTANCE AROUND 1 3/16" EXHAUST VALVE = 3.73"
INTAKE
EXHAUST
DISTANCE AROUND 1 1/4" EXHAUST VALVE = 3.927"
DISTANCE AROUND EACH 1 1/8" INTAKE VALVE = 3.54" TOTAL DISTANCE AROUND BOTH VALVES = 7.08"
FIGURE 30–8 Comparing the valve opening areas between a twoand three-valve combustion chamber when the valves are open.
FIGURE 30–10 Four valves in a pentroof combustion chamber.
TECH TIP Horsepower Is Airflow
More total area under the valve is possible when two smaller valves are used rather than one larger valve at the same valve lift. The smaller valves allow smooth low-speed operation (because of increased velocity of the mixture as it enters the cylinder as a result of smaller intake ports). Good high-speed performance is also possible because of the increased valve area and lighter weight valves. SEE FIGURE 30–9. When four valves are used, either the combustion chamber has a pentroof design, with each pair of valves in line, or it is hemispherical, with each valve on its own axis. SEE FIGURE 30–10. Four valves on the pentroof design will be operated with dual overhead camshafts or with single overhead camshafts and rocker arms. When four valves are used, it is possible to place the spark plug at the center of the combustion chamber.
INTAKE AND EXHAUST PORTS PURPOSE AND FUNCTION
The part of the intake or exhaust system passage that is cast in the cylinder head is called a port. Ports lead from the manifolds to the valves. The most desirable port
To get more power from an engine, more air needs to be drawn into the combustion chamber. One way to achieve more airflow is to increase the valve and port size of the cylinder heads along with a change in camshaft lift and duration to match the cylinder heads. One popular, but expensive, method is to replace the stock cylinder heads with high-performance cast-iron or aluminum cylinder heads. Some vehicle manufacturers, such as Audi, go to great expense to design high-flow rate cylinder heads by installing five-valve cylinder heads on some of their highperformance engines. SEE FIGURE 30–11.
shape is not always possible because of space requirements in the head. Space is required for the head bolt bosses, valve guides, cooling passages, and pushrod openings. Inline engines may have both intake and exhaust ports located on the same side of the engine. On some older engines two cylinders share the same port because of the restricted space available. Shared ports are called Siamese ports.
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FIGURE 30–11 An Audi five-valve cylinder head, which uses three intake valves and two exhaust valves.
TECH TIP Unshroud the Intake Valve for More Power If an engine is being rebuilt for high performance, most experts recommend that the shrouded section around the intake valve be removed, thereby increasing the airflow and, therefore, the power that the engine can achieve, especially at higher engine speeds. This process is often called unshrouding.
FIGURE 30–12 The intake manifold design and combustion chamber design both work together to cause the air-fuel mixture to swirl as it enters the combustion chamber. FUEL INJECTOR
INTAKE PORTS
Larger ports and better breathing are possible in engines that have the intake port on one side of the head and the exhaust port on the opposite side. Sometimes a restricting hump within a port may actually increase the airflow capacity of the port. It does this by redirecting the flow to an area of the port that is large enough to handle the flow. Modifications in the field, such as porting or relieving, would result in restricting the flow of such a carefully designed port. The intake port in a cylinder head designed for use with a carburetor or throttle-body-type fuel injection is relatively long, whereas the exhaust port is short. On engines designed for use with port fuel injection, the cylinder head ports are designed to help promote swirl in the combustion chamber, as shown in FIGURE 30–12.
EXHAUST PORTS Like the intake ports, exhaust ports are designed to allow the free flow of exhaust gases from the engine. The length of the exhaust ports is shorter than the intake ports to help reduce the amount of heat transferred to the coolant. SEE FIGURE 30–13.
CYLINDER HEAD PASSAGES COOLANT FLOW PASSAGES
The engine is designed so that coolant will flow from the coolest portion of the engine to the warmest portion. The water pump takes the coolant from the radiator. The coolant is circulated through the block, where it is directed all around the cylinders. The coolant then flows upward through the gasket to the cooling passages cast into the cylinder head. The
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EXHAUST PORT
EXHAUST VALVE
INTAKE VALVE
INTAKE PORT
FIGURE 30–13 A port-injected engine showing the straight freeflowing intake and exhaust ports. heated coolant is collected at a common point and returned to the radiator to be cooled and recycled. NOTE: Reversed-flow cooling systems, such as that used on the Chevrolet LT1 V-8, send the coolant from the radiator to the cylinder heads first. This results in a cooler cylinder head and allows for more spark advance without enginedamaging detonation. Typical
coolant
FIGURE 30–14.
passages
in
a
head
are
shown
in
FIGURE 30–14 A cutaway head showing the coolant passages in green.
(a)
(b)
(c)
FIGURE 30–16 Overhead camshafts may be (a) held in place with bearing caps, (b) supported by towers, or (c) fitted into bearing bores machined directly into the head.
FIGURE 30–15 Coolant flows through the cylinder head, and the passages are sealed by the head gasket.
CYLINDER HEAD SERVICING CYLINDER HEAD SERVICING SEQUENCE
HEAD GASKET HOLES
There are relatively large holes in the gasket surface of the head leading to the head cooling passages. The openings between the head and the block are usually too large for the correct coolant flow. When the openings are too large, the head gasket performs an important coolant flow function. Specialsize and smaller holes are made in the gasket. These holes correct the coolant flow rate at each opening. Therefore, it is important that the head gasket be installed correctly for proper engine cooling. SEE FIGURE 30–15.
LUBRICATING OIL PASSAGES
Lubricating oil is delivered to the overhead valve mechanism, either through the valve pushrods or through drilled passages in the head and block casting. There are special openings in the head gasket to allow the oil to pass between the block and head without leaking. After the oil passes through the valve mechanisms, it returns to the oil pan through oil return passages. Some engines have drilled oil return holes, but most engines have large cast holes that allow the oil to return freely to the engine oil pan. The cast holes are large and do not easily become plugged. NOTE: Many aluminum cylinder heads have smaller-thannormal drainback holes. If an engine has excessive oil consumption, check the drain holes before removing the engine.
Although not all cylinder heads require all service operations, cylinder heads should be reconditioned using the following sequence. 1. Disassemble and thoroughly clean the heads. (See Chapter 25.) 2. Check for cracks and repair as necessary. (See Chapter 25.) 3. Check the surface that contacts the engine block and machine, if necessary. (See discussion later in this chapter.) 4. Check valve guides and replace or service, as necessary. (See discussion later in this chapter.) 5. Grind valves and reinstall them in the cylinder head with new valve stem seals. (See Chapter 27.)
DISASSEMBLING OVERHEAD CAMSHAFT HEAD The overhead camshaft will have either one-piece bearings in a solid bearing support or split bearings and a bearing cap. When onepiece bearings are used, the valve springs will have to be compressed with a fixture or the finger follower will have to be removed before the camshaft can be pulled out endwise. When bearing caps are used, they should be loosened alternately so that bending loads are not placed on either the cam or bearing caps. SEE FIGURES 30–16 AND 30–17. VALVE TRAIN DISASSEMBLY
Disassemble the cylinder head as discussed in Chapter 24. All valve train components that are to be reused must be kept together. As wear occurs, parts are worn together.
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3
5
7
2
1 2
3
4 5
1
8
6
4
FIGURE 30–17 Always follow the specified loosening sequence to prevent valve spring tension from bending the camshaft.
FIGURE 30–19 Cylinder heads should be checked in five planes for warpage, distortion, bend, and twist. FEELER GAUGE STRAIGHT EDGE
CYLINDER HEAD
FIGURE 30–18 Pushrods can be kept labeled if stuck through a cardboard box. Individual parts become worn together. Using cardboard is a crude but effective material to keep all valve train parts together and labeled exactly as they came from the engine.
Be sure to keep the top part of the pushrod at the top.
Keep the rocker arms with the same pushrods as they wear together.
Intake and exhaust valve springs can be different and must be kept with the correct valve.
SEE FIGURE 30–18.
CYLINDER HEAD INSPECTION The surface must be thoroughly cleaned and inspected as follows: STEP 1
After removing the old gasket material, use a file and draw it across the surface of the head to remove any small burrs.
STEP 2
The head should be checked in five planes. Checking the cylinder head gasket surface in five planes checks the head for warpage, distortion, bend, and twist. SEE FIGURE 30–19.
These defects are determined by trying to slide a 0.004 in. (0.1 mm) feeler gauge under a precision straightedge held against the head surface. The clearance between the cylinder head and the straightedge should not vary by over 0.002 in. (0.05 mm) in any 6 in. (15 cm) length, or by more than 0.004 in. overall. Always check the manufacturer’s recommended specifications. SEE FIGURE 30–20. NOTE: The cylinder head surface that mates with the top deck of the block is often called the fire deck. NOTE: Always check the cylinder head thickness and specifications to be sure that material can be safely removed from the surface. Some manufacturers do not recommend any machining, but rather require cylinder head replacement if cylinder head surface flatness is not within specifications.
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FIGURE 30–20 A precision ground straightedge and a feeler gauge are used to check the cylinder head for flatness.
FIGURE 30–21 Warped overhead camshaft cylinder head. If the gasket surface is machined to be flat, the camshaft bearings will still not be in proper alignment. The solution is to straighten the cylinder head or to align bore the cam tunnel.
ALUMINUM CYLINDER HEAD STRAIGHTENING PURPOSE AND FUNCTION Aluminum expands at about twice the rate of cast iron when heated. Aluminum cylinder heads used on cast-iron blocks can warp and/or crack if they are overheated. The expanding cylinder head first hits the head bolts. Further expansion of the head causes the head to expand upward and bow in the center. If a warped (bowed) cylinder head is resurfaced, the stresses of expansion are still present, and if the cylinder head uses an overhead camshaft, further problems exist. If the cylinder head is distorted into a D shape, the camshaft centerline bearing supports must also be restored. SEE FIGURE 30–21. To restore the straightness of the cam bearing bore (sometimes called the cam tunnel), align boring and/or honing may be necessary.
The best approach to restore a warped aluminum cylinder head (especially an overhead camshaft head) is to relieve the stress that has caused the warpage and to straighten the head before machining. STEP 1
Determine the amount of warpage with a straightedge and thickness (feeler) gauge. Cut shim stock (thin strips of metal) to one-half of the amount of the warpage. Place shims of this thickness under each end of the head.
STEP 2
Tighten the center of the cylinder head down on a strong, flat base. A 2 in. thick piece of steel that is 8 in. wide by 20 in. long makes a good support for the gasket surface of the cylinder head (use antiseize compound on the bolt threads to help in bolt removal).
STEP 3
Place the head and base in an oven for five hours at 500°F (260°C). Turn the oven off and leave the assembly in the oven.
NOTE: If the temperature is too high, the valve seat inserts may fall out of the head! At 500°F, a typical valve seat will still be held into the aluminum head with a 0.002 in. interference fit based on calculations of thermal expansion of the aluminum head and steel insert. Allow the head to cool in the oven for four to five hours to relieve any stress in the aluminum from the heating process. For best results, the cooling process should be allowed to occur overnight. Several cylinder heads can be “cooked” together. If the cylinder head is still warped, the heating and cooling process can be repeated. After the head is straightened and the stress relieved, the gasket surface (fire deck) can be machined in the usual manner. To prevent possible camshaft bore misalignment problems, do not machine more than 0.01 to 0.015 in. (0.25 to 0.38 mm) from the head gasket surface.
CYLINDER HEAD RESURFACING REFINISHING METHODS
Milling or broaching
Grinding
FIGURE 30–22 A cast-iron cylinder head being resurfaced using a surface grinder.
TECH TIP The Potato Chip Problem Most cylinder heads are warped or twisted in the shape of a typical potato chip (high at the ends and dipped in the center). After a cylinder head is ground, the surface should be perfectly flat. A common problem involves grinding the cylinder head in both directions while it is being held on the table that moves to the left and right. Most grinders are angled by about 4 degrees. The lower part of the stone should be the cutting edge. If grinding occurs along the angled part of the stone, then too much heat is generated. This heat warps the head (or block) upward in the middle. The stone then removes this material, and the end result is a slight (about 0.0015 in.) depression in the center of the finished surface. To help prevent this from happening, always feed the grinder in the forward direction only (especially during removal of the last 0.003 in. of material).
Two common resurfacing methods are:
A milling type of resurfacer uses metal-cutting tool bits fastened in a disc. This type is also called a broach. The disc is the rotating workhead of the mill. The surface grinder type uses a large-diameter abrasive wheel. Both types of resurfacing can be done with table-type and with precision-type surfacers. With a table-type surfacer, the head or block is passed over the cutting head that extends slightly above a worktable. The abrasive wheel is dressed before grinding begins. The wheel head is adjusted to just touch the surface. At this point, the feed is calibrated to zero. This is necessary so that the operator knows exactly the size of the cut being made. Light cuts are taken. The abrasive wheel cuts are limited to 0.005 in. (0.015 mm). SEE FIGURE 30–22. The abrasive wheel surface should be wire brushed after each five passes, and the wheel should be redressed after grinding each 0.1 in. (2.5 mm). The mill-type cutting wheel can remove up to 0.03 in. (0.075 mm) on each pass. A special mill-cutting tool or a dull grinding wheel is used when aluminum heads are being resurfaced.
NOTE: Resurfacing the cylinder head changes the compression ratio of the engine by about 1/10 point per 0.01 in. of removed material. For example, the compression ratio would be increased from 9.0:1 to 9.2:1 if 0.02 in. were removed from a typical cylinder head.
SURFACE FINISH
The surface finish of a reconditioned part is as important as the size of the part. Surface finish is measured in units called microinches (abbreviated “ in.”). The symbol in front of the inch abbreviation is the Greek letter mu. One microinch equals 0.000001 in., or 0.025 micrometer (m). The finish classification in microinches gives the distance between the highest peak and the deepest valley. The usual method of expressing surface finish is by the arithmetic average roughness height (RA), that is, the average of the distances of all peaks and valleys from the mean (average) line. Surface finish is measured using a machine with a diamond stylus. SEE FIGURE 30–23. Another classification of surface finish, which is becoming obsolete, is called the root-mean-square (RMS). The RMS is a slightly higher number and can be obtained by multiplying RA 1.11.
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ALL PEAKS AND VALLEYS AVERAGED
RA
LENGTH OF SAMPLE
FIGURE 30–23 A graph showing a typical rough surface as would be viewed through a magnifying glass. RA is an abbreviation indicating the average height of all peaks and valleys. AMOUNT OF METAL TO BE REMOVED FROM THE INTAKE SIDE OF THE HEAD B ANGLE SURFACE C
A
ANGLE 90° 85° 80° 75° 70° 65° 60°
AMOUNT TO BE REMOVED FROM B A × 1.000 A × 1.100 A × 1.233 A × 1.414 A × 1.673 A × 2.067 A × 2.733
THE AMOUNT REMOVED AMOUNT OF FROM SURFACE C IS METAL REMOVED 1.4 × A FROM THE RESURFACED HEAD
FIGURE 30–24 The material that must be removed for a good manifold fit. Typical surface finish roughness recommendations for castiron and aluminum cylinder heads and blocks include the following: Cast Iron Maximum: 110 RA (125 RMS) (Rough surfaces can limit gasket movement and conformity.) Minimum: 30 RA (33 RMS) (Smoother surfaces increase the tendency of the gasket to flow and reduce gasket sealing ability.) Recommended range: 60 to 100 RA (65 to 110 RMS) Aluminum Maximum: 60 RA (65 RMS) Minimum: 30 RA (33 RMS) Recommended range: 50 to 60 RA (55 to 65 RMS) The rougher the surface is, the higher the microinch finish measurement will be. Typical preferred microinch finish standards for other engine components include the following: Crank and rod journal:
10 to 14 RA (12 to 15 RMS)
Honed cylinder:
18 to 32 RA (20 to 35 RMS)
Connecting rod big end: 45 to 72 RA (50 to 80 RMS)
INTAKE MANIFOLD ALIGNMENT PURPOSE
The intake manifold of a V-type engine may no longer fit correctly after the gasket surfaces of the heads are ground. The ports and the assembly bolt holes may no longer
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FIGURE 30–25 Using an intake manifold template to check for the proper angles after the cylinder heads have been machined.
match. The intake manifold surface must be resurfaced to remove enough metal to rematch the ports and bolt holes. The amount of metal that must be removed depends on the angle between the head gasket surface and the intake manifold gasket surface. SEE FIGURE 30–24.
PROCEDURE Automotive machine shops that perform head resurfacing have tables that specify the exact amount of metal to be removed. It is usually necessary to also remove some metal from both the front and the back gasket surfaces of closed-type intake manifolds used on V-type engines. This is necessary to provide a good gasket seal that will prevent oil leakage from the lifter valley. SEE FIGURE 30–25.
VALVE GUIDE INSERTS ALUMINUM CYLINDER HEAD
FIGURE 30–27 All aluminum cylinder heads use valve guide inserts. INTEGRAL VALVE GUIDE WEAR
WEAR
WEAR
WEAR
FIGURE 30–26 An integral valve guide is simply a guide that has been drilled into the cast-iron cylinder head.
CAUTION: Do not remove any more material than is necessary to restore a flat cylinder head-to-block surface. Some manufacturers limit total material that can be removed from the block deck and cylinder head to 0.008 in. (0.2 mm). Removal of material from the cylinder head of an overhead camshaft engine shortens the distance between the camshaft and the crankshaft. This causes the valve timing to be retarded unless a special copper spacer shim is placed between the block deck and the gasket to restore proper crankshaft-to-camshaft centerline dimension.
FIGURE 30–28 Valve guides often wear to a bell-mouth shape to both ends due to the forces exerted on the valve by the valve train components.
cause of valve stem and guide wear. The movement of the valve causes both the top and bottom ends of the guide to wear until the guide has bell-mouth shapes at both ends. SEE FIGURE 30–28.
VALVE STEM-TO-GUIDE CLEARANCE
VALVE GUIDES TYPES The valve guide supports the valve stem so that the valve face will remain perfectly centered, or concentric, with the valve seat. The valve guide is generally integral with the head casting in cast-iron heads for better heat transfer and for lower manufacturing costs. SEE FIGURE 30–26. Removable or pressed-in valve guides and valve seat inserts are always used in aluminum heads. SEE FIGURE 30–27. No matter how good the valves or seats are, they cannot operate properly if the valve guide is not accurate. In use, the valve opening mechanism pushes the valve tip sideways. This is the major
Engine manufacturers usually recommend the following valve stem-to-guide clearances.
Intake valve: 0.001 to 0.003 in. (0.025 to 0.076 mm)
Exhaust valve: 0.002 to 0.004 in. (0.05 to 0.1 mm)
Be sure to check the exact specifications for the engine being serviced. The exhaust valve clearance is greater than the intake valve clearance because the exhaust valve runs hotter and therefore expands more than the intake valve. Excessive valve stem-to-guide clearance can cause excessive oil consumption. The intake valve guide is exposed to manifold vacuum that can draw oil from the top of the cylinder head down into the combustion chamber. In this situation, valves can also run hotter than usual because much of the heat in the valve is transferred to the cylinder head through the valve guide.
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VALVE LIFTED OFF SEAT
DIAL INDICATOR (GAUGE)
FIGURE 30–29 A small-hole gauge and a micrometer are being used to measure the valve guide. The guide should be measured in three places: at the top, middle, and bottom.
FIGURE 30–31 Measuring valve guide-to-stem clearance with a dial indicator while rocking the stem in the direction of normal thrust. The reading on the dial indicator should be compared to specifications because it does not give the guide-to-stem clearance directly. The valve is usually held open to its maximum operating lift.
?
FREQUENTLY ASKED QUESTION
What Is Valve Guide Knurling?
FIGURE 30–30 The diameter of the valve stem is being measured using a micrometer. The difference between the inside diameter of the valve guide and the diameter of the valve stem is the valve guide-to-stem clearance.
HINT: A human hair is about 0.002 in. (0.05 mm) in diameter. Therefore, the typical clearance between a valve stem and the valve guide is only the thickness of a human hair.
MEASURING VALVE GUIDES Valves should be measured for stem wear before valve guides are measured. The valve guide is measured in the middle with a small-hole gauge. The gauge size is checked with a micrometer. The guide is then checked at each end. The expanded part of the ball should be placed crosswise to the engine where the greatest amount of valve guide wear exists. The dimension of the valve stem diameter is subtracted from the dimension of the valve guide diameter. If the clearance exceeds the specified clearance, then the valve guide will have to be reconditioned. SEE FIGURES 30–29 AND 30–30. Valve stem-to-guide clearance can also be checked using a dial indicator (gauge) to measure the amount of movement of the valve when lifted off the valve seat. SEE FIGURE 30–31. OVERSIZE STEM VALVES Some domestic vehicle manufacturers that have integral valve guides in their engines recommend reaming worn valve guides and installing new valves with oversize
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In an old and now outdated process known as valve guide knurling, a tool is rotated as it is driven into the guide. The tool displaces the metal to reduce the hole diameter of the guide. Knurling is ideally suited to engines with integral valve guides (guides that are part of the cylinder head and are nonremovable). It is recommended that knurling not be used to correct wear exceeding 0.006 in. (0.15 mm). In the displacing process, the knurling tool pushes a small tapered wheel or dull threading tool into the wall of the guide hole. This makes a groove in the wall of the guide, similar to a threading operation without removing any metal. The metal piles up along the edge of the groove just as dirt would pile up along the edge of a tire track as the tire rolled through soft dirt. (The dirt would be displaced from under the wheel to form a small ridge alongside the tire track.) SEE FIGURE 30–32. The knurling tool is driven by an electric drill and an attached speed reducer that slows the rotating speed of the knurling tool. The reamers that accompany the knurling set will ream just enough to provide the correct valve stem clearance for commercial reconditioning standards. The valve guides are honed to size in the precision shop when precise fits are desired. Clearances of knurled valve guides are usually one-half of the new valve guide clearances. Such small clearance can be used because knurling leaves so many small oil rings down the length of the guide for lubrication.
(OS) stems. When a valve guide is worn, the valve stem is also likely to be worn. In this case, new valves are required. If new valves are used, they can just as well have oversize stems as standard stems. Typically, available sizes include 0.003, 0.005, 0.015, and 0.03 in. OS. The valve guide is reamed or honed to the correct size to fit the oversize stem of the new valve.
ORIGINAL INSIDE DIAMETER OF GUIDE
DRIVER
HEAD
NEW VALVE GUIDE BEING INSTALLED
HEAD
RAISED AREAS CAUSED BY KNURLING
OLD VALVE GUIDE SUPPORT BLOCKS BEING REMOVED RESTORED INSIDE DIAMETER OF GUIDE
FIGURE 30–33 Valve guide replacement procedure.
FIGURE 30–32 Sectional view of a knurled valve guide. TECH TIP Tight Is Not Always Right Many engine manufacturers specify a valve stem-toguide clearance of 0.001 to 0.003 in. (0.025 to 0.076 mm). However, some vehicles, especially those equipped with aluminum cylinder heads, may specify a much greater clearance. For example, many Chrysler 2.2 liter and 2.5 liter engines have a specified valve stem-to-guide clearance of 0.003 to 0.005 in. (0.076 to 0.127 mm). This amount of clearance feels loose to those technicians accustomed to normal valve stem clearance specifications. Although this large amount of clearance may seem excessive, remember that the valve stem increases in diameter as the engine warms up. Therefore, the operating clearance is smaller than the clearance measured at room temperature. Always double-check factory specifications before replacing a valve guide for excessive wear.
The resulting clearance of the valve stem in the guide is the same as the original clearance. The oil clearance and the heat transfer properties of the original valve and guide are not changed when new valves with oversize stems are installed. NOTE: Many remanufacturers of cylinder heads use oversize valve stems to simplify production.
VALVE GUIDE REPLACEMENT PURPOSE When an engine is designed with replaceable valve guides, their replacement is always recommended when the valve assembly is being reconditioned. The original valve guide height should be measured before the guide is removed so that the new guide can be properly positioned. After the valve guide height is measured, the worn guide is pressed from the head with a proper fitting driver. SEE FIGURE 30–33. The driver has a stem to fit the guide opening and a shoulder that pushes on the end of the guide. If the guide has a flange, care should be taken to ensure that the guide is pushed out from the correct end, usually from the port side and toward the rocker arm
side. The new guide is pressed into the guide bore using the same driver. Make sure that the guide is pressed to the correct depth. After the guides are replaced, they are reamed or honed to the proper inside diameter. Replacement valve guides can also be installed to repair worn integral guides. Both cast-iron and bronze guides are available.
VALVE GUIDE SIZES
Three common valve guide sizes are as
follows:
5/16 or 0.313 in.
11/32 or 0.343 in.
3/8 or 0.375 in.
VALVE GUIDE INSERTS
When the integral valve guide is badly worn, it can be reconditioned using an insert. This repair method is usually preferred in heavy-duty and high-speed engines. Two types of guide inserts are commonly used for guide repair.
Thin-walled bronze alloy sleeve bushing
Spiral bronze alloy bushing
The thin-walled bronze sleeve bushings are also called bronze guide liners. The valve guide rebuilding kit used to install each of these bushings includes all of the reamers, installing sleeves, broaches, burnishing tools, and cutoff tools that are needed to install and properly size the bushings. The valve guide must be bored to a large enough size to accept the thin-walled insert sleeve. The boring tool is held in alignment by a rugged fixture. One type is shown in FIGURE 30–34. Depending on the make of the equipment, the boring fixture is aligned with the valve guide hole, the valve seat, or the head gasket surface. First, the boring fixture is properly aligned. The guide is then bored, making a hole somewhat smaller than the insert sleeve that will be used. The bored hole is reamed to make a precise smooth hole that is still slightly smaller than the insert sleeve. The insert sleeve is installed with a press fit that holds it in the guide. The press fit also helps to maintain normal heat transfer from the valve to the head. The thin-walled insert sleeve is held in an installing sleeve. A driver is used to press the insert from the installing sleeve into the guide. A broach is then pressed through the insert sleeve to firmly seat it in the guide. The broach is designed to put a knurl in the guide to aid in lubrication. The insert sleeve is then trimmed to the valve guide length. Finally, the insert sleeve is reamed or honed to provide the required valve stem clearance. A very close clearance of 0.0005 in. (one-half of one-thousandth of an inch) (0.013 mm) is often used with the bronze thin-walled insert sleeve. SEE FIGURE 30–35.
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DRILL BIT FOR BORING VALVE GUIDE
BORING FIXTURE
FIGURE 30–35 Trimming the top of the thin-walled insert. SCREW THREADS FOR TIGHTENING FIXTURE
FIGURE 30–34 A type of fixture required to bore the valve guide to accept a thin-walled insert sleeve.
TECH TIP Right Side Up When replacing valve guides, it is important that the recommended procedures be followed. Most manufacturers specify that replaceable guides be driven from the combustion chamber side toward the rocker arm side. For example, big block Chevrolet V-8 heads (396, 402, 427, and 454 cu.3) have a 0.004 in. (0.05 mm) taper (small end toward the combustion chamber). Other manufacturers, however, may recommend driving the old guide from the rocker arm side to prevent any carbon buildup on the guide from damaging the guide bore. Always check the manufacturer’s recommended procedures before attempting to replace a valve guide.
SPIRAL BRONZE INSERT BUSHINGS
The spiral bronze alloy insert bushing is screwed into a thread that is put in the valve guide. The tap used to put cut threads in the valve guide has a long pilot ahead of the thread-cutting portion of the tap. This aids in restoring the original guide alignment. The long pilot is placed in the guide from the valve seat end. A power driver is attached to the end of the pilot that extends from the spring end of the valve guide. The threads are cut in the guide from the seat end toward the spring end as the power driver turns the tap, pulling it toward the driver. The tap is stopped before it comes out of the guide, and the power driver is removed. The thread is carefully completed by hand to avoid breaking either the end of the guide or the tap. An installed spiral bronze insert bushing can be seen in FIGURE 30–36. The spiral bronze bushing is tightened on an inserting tool. This holds it securely in the wound-up position so that it can be screwed into the spring end of the guide. It is screwed in until the bottom of the
FIGURE 30–36 Installed spiral bronze insert bushing.
bushing is flush with the seat end of the guide. The holding tool is removed, and the bushing material is trimmed to one coil above the spring end of the guide. The end of the bushing is temporarily secured with a plastic serrated bushing retainer and a worm gear clamp. This holds the bushing in place as a broach is driven through the bushing to firmly seat it in the threads. The bushing is reamed or honed to size before the temporary bushing retainer is removed. The final step is to trim the end of the bushing with a special cutoff tool that is included in the bushing installation tool set. This type of spiral bronze bushing can be removed by using a pick to free the end of the bushing. It can then be stripped out and a new bushing inserted in the original threads in the guide hole. New threads do not have to be put in the guide. The spiral bushing design has natural spiral grooves to hold oil for lubrication. The valve stem clearances are the same as those used for knurling and for the thin-walled insert (about one-half of the standard recommended clearance).
REVIEW QUESTIONS 1. What is meant by the term crossflow head?
3. What is the recommended cylinder head reconditioning sequence?
2. What is a Siamese port?
4. What are the advantages of using four valves per cylinder?
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CHAPTER QUIZ 1. Cylinder heads with four valves flow more air than those with two valves because they ______________. a. Have a greater open area b. Use a higher lift camshaft c. Increase the velocity of the air d. Both a and c
6. Some vehicle manufacturers recommend repairing integral guides with ______________. a. OS stem valves b. Knurling c. Replacement valve guides d. Valve guide inserts
2. Two technicians are discussing a Hemi engine. Technician A says that a Hemi is an engine with a hemispherical-shaped combustion chamber. Technician B says that all Hemi engines are cam-in-block designs. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
7. Typical valve stem-to-guide clearance is ______________. a. 0.03 to 0.045 in. (0.8 to 1 mm) b. 0.015 to 0.02 in. (0.4 to 0.5 mm) c. 0.005 to 0.01 in. (0.13 to 0.25 mm) d. 0.001 to 0.004 in. (0.03 to 0.05 mm)
3. Technician A says that an Audi five-valve engine uses three intake valves and two exhaust valves. Technician B says that it uses three exhaust valves and two intake valves. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 4. The gasket surface of a cylinder head, as measured with a precision straightedge, should have a maximum variation of ______________. a. 0.002 in. in any 6 in. length, or 0.004 in. overall b. 0.001 in. in any 6 in. length, or 0.004 in. overall c. 0.020 in. in any 10 in. length, or 0.02 in. overall d. 0.004 in. in any 10 in. length, or 0.008 in. overall 5. A warped aluminum cylinder head can be restored to useful service by ______________. a. Grinding the gasket surface and then align honing the camshaft bore b. Heating it in an oven at 500°F with shims under each end, allowing it to cool, and then machining it c. Heating it to 500°F for five hours and cooling it rapidly before final machining d. Machining the gasket surface to one-half of the warped amount and then heating the head in an oven and allowing it to cool slowly
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8. What other engine component may have to be machined if the cylinder heads are machined on a V-type engine? a. Exhaust manifold b. Intake manifold c. Block deck d. Distributor mount (if the vehicle is so equipped) 9. Which type of valve guide is most used in a cast-iron head? a. Integral b. Bronze c. Powdered metal (PM) d. Thin-walled sleeve type 10. Which statement is true about surface finish? a. Cast-iron surfaces should be smoother than aluminum surfaces. b. The rougher the surface, the higher the microinch finish measurement. c. The smoother the surface, the higher the microinch finish measurement. d. A cylinder head should be much smoother than a crankshaft journal.
VALVE AND SEAT SERVICE
OBJECTIVES: After studying Chapter 31, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “B” (Cylinder Head and Valve Train Diagnosis and Repair). • Discuss various engine valve types and materials. • Describe how to test valve springs. • Explain the purpose, function, and operation of valve rotators. • List the steps necessary to reface a valve. • Describe how to reface or replace valve seats. • Discuss how to measure and correct installed height and valve stem height. KEY TERMS: Expandable pilots 303 • Finishing stone 304 • Free rotators 299 • Hard seat stones 304 • Inertia friction welding 295 • Insert seats 296 • Installed height 307 • Integral seat 296 • Locks 294 • Poppet valve 294 • Positive rotators 299 • Retainer 294 • Roughing stone 304 • Stellite® 294 • Tapered pilots 303 • Thermal shock 297 • Three-angle valve job 302 • Throating angle 302 • Topping angle 302 • Total indicator runout (TIR) 304 • Truing 300 • Valve face 294 • Valve face angle 301 • Valve float 299 • Valve guide 294 • Valve seat 294 • Valve spring 294 • Valve spring inserts (VSI) 307 • Valve spring surge 299 • Valve stem height 307 • Variable rate springs 299
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VALVE TIP
KEEPERS
KEEPER GROOVE RETAINER
OUTER VALVE SPRING
STEM
VALVE FACE
FILLET
INNER VALVE SPRING
PROPER SEAT CONTACT AREA COMBUSTION SURFACE
SEAL MARGIN
VALVE HEAD
FIGURE 31–1 Identification of the parts of a valve. SPRING SEAT
INTAKE AND EXHAUST VALVES
FIGURE 31–2 Typical valve spring and related components. Dual valve springs are used to reduce valve train vibrations and a spring seat is used to protect aluminum heads.
TERMINOLOGY
Automotive engine valves are of a poppet valve design. The term poppet refers to the shape of the valve and their operation in automotive engines. The valve is opened by means of a valve train that is operated by a cam. The cam is timed to the piston position and crankshaft cycle. The valve is closed by one or more springs. Typical valves are shown in FIGURE 31–1. Intake valves control the inlet of cool, low-pressure induction charges. Exhaust valves handle hot, high-pressure exhaust gases. This means that exhaust valves are exposed to more severe operating conditions. They are, therefore, made from much higher quality materials than the intake valves, which makes them more expensive. The valve is held in place and is positioned in the head by the valve guide. The portion of the valve that seals against the valve seat in the cylinder head is called the valve face. The face and seat will have an angle of either 30 or 45 degrees, which are the nominal angles; actual service angles may vary. Most engines use a nominal 45-degree valve and seat angle.
intake valve must be larger than the exhaust valve to handle the same mass of gas. The larger intake valve controls lowvelocity, low-density gases. The distance the valve opens is close to 25% of the valve head diameter.
SEE FIGURE 31–3.
VALVE MATERIALS
Alloy steel. Alloys used in exhaust valve materials are largely of chromium for oxidation resistance, with small amounts of nickel, manganese, and nitrogen added. Heat-treating is used whenever it is necessary to produce special valve properties.
Stellite®. An alloy of nickel, chromium, and tungsten, Stellite® is nonmagnetic. Some valves use this product just only on the tip of the valve to help reduce wear in places where the rocker arm contacts the valve stem on engines that do not use a roller rocker arm. Stellite® is also used on some valve faces.
Inconal®. A type of alloy containing nickel, chrome, and iron and is used mostly in racing engines.
Titanium. About half the weight of conventional valves, titanium reduces the tension on valve springs resulting in higher RPM engine operation. The valve stems are often moly coated to help prevent sticking in the valve guide.
Stainless steel. Used in many heavy-duty applications, stainless steel often uses chrome-plated valve stems and Stellite tips to improve long-term durability.
Aluminized. The valve is aluminized where corrosion may be a problem. Aluminized valve facing reduces valve recession
PARTS INVOLVED
A valve spring holds the valve against the seat. The valve keepers (also called locks) secure the spring retainer to the stem of the valve. For valve removal, it is necessary to compress the spring and remove the valve keepers. Then the spring, valve seals, and valve can be removed from the head. A typical valve assembly is shown in FIGURE 31–2.
VALVE SIZE RELATIONSHIPS
Extensive testing has shown that a normal relationship exists between the different dimensions of valves.
Intake valves. Engines with cylinder bores that measure from 3 to 8 in. (80 to 200 mm) will have intake valve head diameters that measure approximately 45% of the bore size. The
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Exhaust valves. The exhaust valve head diameter is approximately 38% of the cylinder bore size. Exhaust valve heads are, therefore, approximately 85% of the size of intake valve heads. The exhaust valve, however, controls high-velocity, high-pressure, denser gases. These gases can be handled by a smaller valve.
INTAKE VALVES
STEM MATERIAL
WELDED JOINT
HEAD MATERIAL
EXHAUST VALVES
FIGURE 31–3 The intake valve is larger than the exhaust valve because the intake charge is being drawn into the combustion chamber at a low speed due to differences in pressure between atmospheric pressure and the pressure (vacuum) inside the cylinder. The exhaust is actually pushed out by the piston and, therefore, the size of the valve does not need to be as large, leaving more room in the cylinder head for the larger intake valve.
FIGURE 31–4 Inertia welded valve stem and head before machining.
TECH TIP Hot Engine ⴙ Cold Weather ⴝ Trouble Serious valve damage can occur if cold air reaches hot exhaust valves soon after the engine is turned off. An engine equipped with exhaust headers and/or straightthrough mufflers can allow cold air a direct path to the hot exhaust valve. The exhaust valve can warp and/or crack as a result of rapid cooling. This can easily occur during cold windy weather when the wind can blow cold outside air directly up the exhaust system. Using reverse-flow mufflers with tailpipes and a catalytic converter reduces the possibilities of this occurring.
when unleaded gasoline is used. Aluminum oxide forms to separate the valve steel from the cast-iron seat to keep the face metal from sticking.
TWO-MATERIAL VALVES
Some exhaust valves are manufactured from two different materials when a one-piece design cannot meet the desired hardness and corrosion resistance specifications. The joint cannot be seen after valves have been used. The valve heads are made from special alloys that can operate at high temperatures, have physical strength, resist lead oxide corrosion, and have indentation resistance. These heads are welded to stems that have good wear resistance properties. These types of valves are usually welded together using a process called inertia friction welding. Inertia friction welding is performed by spinning one end and then forcing the two pieces together until the materials reach their melting temperature. Then the parts are held together until they fuse, resulting in a uniform weld between two different materials. FIGURE 31–4 shows an inertia welded valve before final machining.
FIGURE 31–5 A sodium-filled valve uses a hollow stem, which is partially filled with metallic sodium (a liquid when hot) to conduct heat away from the head of the valve. WARNING If a sodium-filled valve is damaged and the sodium leaks out, it can cause a fire if exposed to water. Sodium reacts violently when exposed to water and burns uncontrollably.
SODIUM-FILLED VALVES Some heavy-duty applications use hollow stem exhaust valves that are partially filled with metallic sodium. The sodium in the valve becomes a liquid at operating temperatures. As it splashes back and forth in the valve stem, the sodium transfers heat from the valve head to the valve stem. The heat goes through the valve guide into the coolant. In general, a onepiece valve design using properly selected materials will provide satisfactory service for automotive engines. SEE FIGURE 31–5.
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VALVE
VALVE
VALVE KEEPER
RETAINER
RETAINER VALVE SPRING
VALVE KEEPER
VALVE SPRING VALVE GUIDE
VALVE GUIDE
INSERT VALVE SEAT
INTEGRAL VALVE SEAT
FIGURE 31–6 Integral valve seats are machined directly into the cast-iron cylinder head and are induction hardened to prevent wear.
FIGURE 31–7 Insert valve seats are a separate part that is interference fitted to a counterbore in the cylinder head.
VALVE SEATS INTEGRAL SEATS The valve face closes against a valve seat to seal the combustion chamber. The seat is generally formed as part of the cast-iron head of automotive engines, called an integral seat. SEE FIGURE 31–6. The seats are usually induction hardened so that unleaded gasoline can be used. This minimizes valve recession as the engine operates. Valve recession is the wearing away of the seat, so that the valve sits farther into the head. INSERT SEATS
An insert seat fits into a machined recess in the steel or aluminum cylinder head. Insert seats are used in all aluminum head engines and in applications for which corrosion and wear resistance are critical. Aluminum heads also include insert valve guides. The exhaust valve seat runs as much as 180°F (100°C) cooler in aluminum heads than in cast-iron heads, because aluminum conducts heat faster than cast iron. Insert seats are also used to recondition integral valve seats that have been badly damaged. SEE FIGURE 31–7.
VALVE FAULT DIAGNOSIS Careful inspection of the cylinder head and valves can often reveal the root cause of failure.
POOR VALVE SEATING Poor seating results from too small a valve lash, hard carbon deposits, valve stem deposits, excessive valve stem-to-guide clearances, or out-of-square valve guide and seat. A valve seat recession can result from improper valve lash adjustments on solid lifter engines. It can also result from misadjustments on a valve train using hydraulic lifters. The valve clearance will also be reduced as a result of valve head cupping or valve face and seat wear. FIGURE 31–8 shows typical intake valve and seat wear.
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FIGURE 31–8 Typical intake valve seat wear.
CARBON DEPOSITS If there is a large clearance between the valve stem and guide or faulty valve stem seals, too much oil will go down the stem. This will increase deposits, as shown on the intake valve in FIGURE 31–9. In addition, a large valve guide clearance will allow the valve to cock or lean sideways, especially with the effect of the rocker arm action. Continued cocking keeps the valve from seating properly and causes it to leak, burning the valve face. SEE FIGURE 31–10. Sometimes, the cylinder head will warp slightly as the head is tightened to the block deck during assembly. In other cases, heating and cooling will cause warpage. When head warpage causes valve guide and seat misalignment, the valve cannot seat properly and it will leak, burning the valve face. EXCESSIVE TEMPERATURES High valve temperatures occur when the valve does not seat properly. Root causes include the following: 1. Cooling system passages in the head may be partially blocked by faulty casting or by deposits built up from the coolant. A corroded head gasket will change the coolant flow. This can cause overheating when the coolant is allowed to flow to the wrong places. 2. Extremely high temperatures are also produced by preignition and by detonation. These conditions are the result of abnormal
BROKEN HEAD OF A VALVE PISTON
VALVE STEM BROKEN OFF
FIGURE 31–9 Carbon deposits on the intake valve are often caused by oil getting past the valve stems or fuel deposits.
VALVE STEM WEAR
FIGURE 31–12 Note the broken piston caused by a valve breaking from the stem.
VALVE SEAT EROSION
Valve seats can wear especially in those engines that were designed for use with leaded gasoline (prior to 1975). Without lead, the valve movement against the seat tears away tiny iron oxide particles during engine operation. The valve movement causes these particles of iron oxide to act like valve grinding compound, cutting into the valve seat surface. As the valve seat is eroded, the valve recedes farther into the cylinder head. When the valve seat erodes, the valve lash decreases. This can lead to valve burning because the valve may not close all the way.
HIGH-VELOCITY SEATING FIGURE 31–10 Excessive wear of the valve stem or guide can cause the valve to seat in a cocked position.
High-velocity seating is indicated by excessive valve face wear, valve seat recession, and impact failure. It can be caused by excessive lash in mechanical lifters and by collapsed hydraulic lifters. Lash allows the valve to hit the seat without the effects of the cam ramp to ease the valve onto its seat. Excessive lash may also be caused by wear of parts, such as the cam, lifter base, pushrod ends, rocker arm pivot, and valve tip. Weak or broken valve springs allow the valves to float away from the cam lobes so that the valves are uncontrolled as they hit the seat. Impact breakage may occur under the valve head or at the valve keeper grooves. The break lines radiate from the starting point. Impact breakage may also cause the valve head to fall into the combustion chamber. In most cases, it will ruin the piston before the engine can be stopped. This situation causes catastrophic engine damage and is described in the field by several terms, including:
Sucking a valve
Dropping a valve
Swallowing a valve
SEE FIGURE 31–12. FIGURE 31–11 Valve face guttering caused by thermal shock. combustion. Both of these produce a very rapid increase in temperature that can cause uneven heating. The rapid increase in temperature will give a thermal shock to the valve. (A thermal shock is a sudden change in temperature.) The shock will often cause radial cracks in the valve. The cracks will allow the combustion gases to escape and gutter the valve face. SEE FIGURE 31–11.
VALVE SPRINGS PURPOSE AND FUNCTION
A valve spring holds the valve against the seat when the valve is not being opened. One end of the valve spring is seated against the head. The other end of the spring is attached under compression to the valve stem through a valve spring retainer and a valve spring keeper (lock). SEE FIGURE 31–13.
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TECH TIP Valve Seat Recession and Engine Performance If unleaded fuel is used in an engine without hardened valve seats, valve seat recession is likely to occur over time. Without removing the cylinder heads, how can a technician identify valve seat recession? As the valve seat wears up into the cylinder head, the valve itself also is located farther up in the head. As this wear occurs, the valve clearance (lash) decreases. If hydraulic lifters are used on the engine, this wear will go undetected until the reduction in valve clearance finally removes all clearance (bottoms out) in the lifter. When this occurs, the valve does not seat fully, and compression, power, and fuel economy are drastically reduced. With the valve not closing completely, the valve cannot release its heat and will burn or begin to melt. If the valve burns, the engine will miss and not idle smoothly. If solid lifters are used on the engine, the decrease in valve clearance will first show up as a rough idle only when the engine is hot. As the valve seat recedes farther into the head, low power, rough idle, poor performance, and lower fuel economy will be noticed sooner than if the engine were equipped with hydraulic lifters. To summarize, refer to the following symptoms as valve seat recession occurs.
SPRING MATERIALS AND DESIGN Valves usually have a single inexpensive valve spring. The springs are generally made of chromium vanadium alloy steel. When one spring cannot control the valve, another spring or damper is added. Some valve springs use a flat coiled damper inside the spring. The damper helps to reduce valve seat wear. This eliminates spring surge and adds some valve spring tension. The normal valve spring winds up as it is compressed. This causes a small but important turning motion as the valve closes on the seat. The turning motion helps to keep the wear even around the valve face. SEE FIGURE 31–14. Multiple valve springs are used where large camshaft lobe lifts are required and a single spring does not have enough strength to control the valve.
If dual coil springs are wrapped in same direction, they are used for extra tension.
?
FREQUENTLY ASKED QUESTION
What Is Valve Float? Valve float occurs when the valve continues to stay open after the camshaft lobe has moved from under the lifter. This happens when the inertia of the valve train overcomes the valve spring tension at high engine speeds. SEE FIGURE 31–15.
1. Valve lash (clearance) decreases (valves are not noisy). 2. The engine idles roughly when hot as a result of reduced valve clearance. 3. Missing occurs, and the engine exhibits low power and poor fuel economy, along with a rough idle, as the valve seat recedes farther into the head. 4. As valves burn, the engine continues to run poorly; the symptoms include difficulty in starting (hot and cold engine), backfiring, and low engine power. HINT: If valve lash is adjustable, valve burning can be prevented by adjusting the valve lash regularly. Remember, as the seat recedes, the valve itself recedes, which decreases the valve clearance. Many technicians do not think to adjust valves unless they are noisy. If, during the valve adjustment procedure, a decrease in valve lash is noticed, then valve seat recession could be occurring.
FIGURE 31–14 Valve spring types (left to right): coil spring with equally spaced coils; spring with damper inside spring coil; closely spaced spring with a damper; taper wound coil spring. OVERHEAD CAMSHAFT
VALVE OPEN — VALVE SPRING COMPRESSED
SPRING RETAINER
VALVE STEM
SPLIT KEEPER
VALVE CLOSED — VALVE SPRING RELAXED
VALVE SPRING
SPRING SEAT
FIGURE 31–13 A retainer and two split keepers hold the spring in place on the valve. A spring seat is used on aluminum heads. Otherwise, the spring seat is a machined area in the head.
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FIGURE 31–15 Valve springs maintain tension in the valve train when the valve is open to prevent valve float, but must not exert so much tension that the cam lobes and lifters begin to wear.
4
3
2
1
FIGURE 31–16 All valve springs should be checked for squareness by using a square on a flat surface and rotating the spring while checking. The spring should be replaced if more than 1/16 in. (1.6 mm) is measured between the top of the spring and the square.
If the inner spring or flat damper is wrapped in the opposite direction, it is used as a damper to control spring oscillations. This is done to control valve spring surge and to prevent excessive valve rotation. These are sometimes called surge dampers. Valve spring surge is the tendency of a valve spring to vibrate.
VARIABLE RATE SPRINGS
Variable rate springs, also called progressive rate or variable pitch springs, have uneven spacing between the coils. Where nonprogressive rate (linear) valve springs provide the same rate through all heights, a variable rate valve spring has a different spring rate depending on how much it is compressed. One advantage of using a variable rate spring is that it provides a low seat pressure and still provides the rate needed for high lift camshaft designs. This type of spring is used to help control valve surge.
FIGURE 31–17 One popular type of valve spring tester used to measure the compressed force of valve springs. Specifications usually include (1) free height (height without being compressed), (2) pressure at installed height with the valve closed, and (3) pressure with the valve open to the height specified.
VALVE KEEPERS AND ROTATORS
VALVE SPRING INSPECTION
Valve springs close the valves after they have been opened by the cam. They must close squarely to form a tight seal and to prevent valve stem and guide wear. It is necessary, therefore, that the springs be square and have the proper amount of closing force. The valve springs are checked for squareness by rotating them on a flat surface with a square held against the side. They should be within 1/16 in. (1.6 mm) of being square. Outof-square springs will have to be replaced. SEE FIGURE 31–16. Only the springs that are square should be checked to determine their compressed force. The surge damper is often specified to be removed from the valve spring when the spring force is being checked. Check service information for the exact procedure to follow for the engine being checked. A valve spring scale is used to measure the valve spring force at a specific height measurement. SEE FIGURE 31–17. Another type uses a torque wrench on a lever system to measure the valve spring force. Valve springs are checked for the following: 1. Free height (or length) without being compressed, should be within 1/16 (0.06) in. of specifications.
VALVE KEEPERS Valve keepers (locks) are used on the end of the valve stem to retain the spring. The inside surfaces of the keeper use a variety of grooves or beads. The design depends on the holding requirements. The outside of the keeper fits into a cone-shaped seat in the center of the valve spring retainer. SEE FIGURE 31–18. VALVE ROTATORS Some valve spring retainers have built-in devices called valve rotators. They cause the valve to rotate in a controlled manner as it is opened. The purposes and functions of valve rotators include the following:
Help prevent carbon buildup from forming by providing a “wiping” action of the valve face
Reduce hot spots on the valves by constantly turning them
Help to even out the wear on the valve face and seat
Improve valve guide lubrication The two types of valve rotators are free and positive.
Free rotators simply take the pressure off the valve to allow engine vibration to rotate the valve. SEE FIGURE 31–19.
The opening of the valve forces the valve to rotate. One type of positive rotator uses small steel balls and slight ramps. Each ball moves down its ramp to turn the rotator sections as
2. Pressure with valve closed and height as per specifications 3. Pressure with valve open and height as per specifications Most specifications allow for variations of plus or minus 10% from the published figures.
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LOCKS RETAINERS
BALL-TYPE
SPRING-TYPE
SPRINGS
OIL SEALS
INTAKE VALVE
EXHAUST VALVE
VALVE OPEN
FIGURE 31–18 Valve keepers (also called locks) are tapered so they wedge into a tapered hole in the retainer.
VALVE RETAINER BALL-TYPE
SPRING-TYPE
VALVE STEM
KEEPERS BUTTED TOGETHER
FIGURE 31–19 Notice that there is no gap between the two keepers (ends butted together). As a result, the valve is free to rotate because the retainer applies a force, holding the keepers in place but not tight against the stem of the valve. Most engines, however, do not use free rotators and, therefore, have a gap between the keepers. the valve opens. A second type uses a coil spring. The spring lies down as the valve opens. This action turns the rotator body in relation to the collar. Valve rotators are only used when it is desirable to increase the valve service life, because rotors cost more than plain retainers. SEE FIGURE 31–20.
VALVE RECONDITIONING PROCEDURE After proper cleaning, inspection, and measurement procedures have been completed, valve reconditioning, usually called a “valve job,” can be performed using the following sequence. STEP 1
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The valve stem is lightly ground and chamfered. This step helps to ensure that the valve will rest in the collet (holder of the valve stem during valve grinding) of the valve grinder correctly. This process is often called truing the valve tip.
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VALVE CLOSED
FIGURE 31–20 Type of valve rotator operation. Ball-type operation is on the left and spring-type operation is on the right. STEP 2
The face of the valve is ground to the proper angle using a valve grinder.
STEP 3
The valve seat is ground in the head. (The seat must be matched to the valve that will be used in that position.)
STEP 4
Valve spring installed height and valve stem height are checked and corrected as necessary.
STEP 5
After a thorough cleaning, the cylinder head should be assembled with new valve stem seals installed.
The rest of the chapter discusses valve face and seat reconditioning, and cylinder head reassembly.
VALVE FACE GRINDING PURPOSE AND FUNCTION Each valve grinder operates somewhat differently. The operation manual that comes with the grinder should be followed for lubrication, adjustment, and specific operating procedures. The general procedures given in the following paragraphs apply to all valve resurfacer equipment. Set the
KNIFE EDGE — NO MARGIN
VALVE FACE
FIGURE 31–21 Resurfacing the face of a valve. Both the valve and the grinder stone or disc are turned to ensure a smooth surface finish on the face of the valve.
FIGURE 31–22 Never use a valve that has been ground to a sharp edge. This weakens the valve and increases the chance of valve face burning.
TECH TIP
grinder head at the valve face angle as specified by the vehicle manufacturer.
Grinding the Valves for More Power
CAUTION: Safety glasses should always be worn for valve and seat reconditioning work. During grinding operations, fine hot chips fly from the grinding stones.
A normal “valve job” includes grinding the face of the valve to clean up any pits and grinding the valve stems to restore the proper stem height. However, a little more airflow in and out of the cylinder head can be accomplished by performing two more simple grinding operations.
NOTE: Some valve grinders use the end of the valve to center the valve while grinding. If the tip of the valve is not square with the stem, the face of the valve may be ground improperly.
• Use the valve grinder and adjust to 30 degrees (for a 45-degree valve) and grind a transition between the valve face and the valve stem area of the valve. While this step may reduce some desirable swirling of the air-fuel mixture at lower engine speeds, it also helps increase cylinder filling, especially at times when the valve is not fully open. • Chamfer or round the head of the valve between the top of the valve and the margin on the side. By rounding this surface, additional airflow into the cylinder is achieved. SEE FIGURE 31–23.
The valve stem is clamped in the work head as close to the fillet under the valve head as possible to prevent vibrations. The work head motor is turned on to rotate the valve. The wheel head motor is turned on to rotate the grinding wheel. The coolant flow is adjusted to flush the material away, but not so much that it splashes. For best results perform the following:
The rotating grinding wheel is fed slowly to the rotating valve face.
Light grinding is done as the valve is moved back and forth across the grinding wheel face.
Do not feed the valve into the grinding stone more than 0.001 to 0.002 in. at one time.
The valve is never moved off the edge of the grinding wheel. It is ground only enough to clean the face. SEE FIGURE 31–21.
MARGIN
The margin is the distance between the head of the valve and the seat of the valve. This distance should be 0.03 in. (0.8 mm). Some vehicle manufacturers specify a minimum margin of less than 0.03 in. for some engines, especially for intake valves. Always check service information for the exact specifications for the engine being serviced. SEE FIGURE 31–22.
NOTE: To help visualize a 0.03 in. margin, note that this dimension is equal to about 1/32 in. or the thickness of a U.S. dime. Intake valves can usually perform satisfactorily with a margin less than 0.03 in. Always check the engine manufacturer’s specifications for the cylinder being serviced. Aluminized valves will lose their corrosion resistance properties when ground. For satisfactory service, aluminized valves must be replaced if they require refacing.
VALVE SEAT RECONDITIONING PURPOSE AND FUNCTION
The valve seats are reconditioned
at the following times:
After the cylinder head has been properly cleaned, resurfaced, and the valve guides have been resized or reconditioned
When the valve guides have been replaced
The final valve seat width and position are checked with the valve that is to be used on the seat being reconditioned.
VALVE SEAT ANGLES Valve seats will have a normal seat angle of either 45 or 30 degrees.
45 degrees. This is the most commonly used, and the narrow 45-degree valve seats will crush carbon deposits to prevent buildup of deposits on the seat and the valve heat will transfer to the seat and cylinder head.
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VALVE FACE
VALVE STEM
FACE ANGLE 44°
CUT BACK (30°)
SEAT ANGLE 45°
VALVE SEAT
VALVE GUIDE
(45°) VALVE FACE MARGIN
VALVE STEM
CUT BACK TO INCREASE FLOW (30°)
FIGURE 31–23 After grinding the 45-degree face angle, additional airflow into the engine can be accomplished by grinding a transition between the face angle and the stem, and by angling or rounding the transition between the margin and the top of the valve.
GRINDING STONE
45°
FIGURE 31–25 Some vehicle manufacturers recommend that the valve face be resurfaced at a 44-degree angle and the valve seat at a 45-degree angle. This 1-degree difference is known as the interference angle.
As the engine operates, the valve will peen itself on the seat. In a short time, it will make a matched seal. After a few thousand miles, the valve will have formed its own seat.
The interference angle has another benefit. The valve and seat are reconditioned with different machines. Each machine must have its angle set before it is used for reconditioning.
It is nearly impossible to set the exact same angles on both valve and seat reconditioning machines. Making an interference angle will ensure that any slight angle difference favors a tight seal at the combustion chamber edge of the valve seat when the valve servicing has been completed. SEE FIGURE 31–25.
VALVE SEAT
VALVE SEAT WIDTH FIGURE 31–24 Grinding a 45-degree angle establishes the valve seat in the combustion chamber.
30 degrees. Usually used on intake valves only. The 30-degree valve seat is more likely to burn than a 45-degree seat because some deposits can build up to keep the valve from seating properly. The 30-degree valve seat will, however, allow more gas flow than a 45-degree valve seat when both are opened to the same amount of lift. SEE FIGURE 31–24.
INTERFERENCE ANGLE
Ideally, the valve face and valve seat should have exactly the same angle. This is impossible, especially on exhaust valves, because the valve head becomes much hotter than the seat and so the valve expands more than the seat. This expansion causes the hot valve to contact the seat in a different place on the valve than it did when it was cold. As a result of its shape, the valve does not expand evenly when heated. This uneven expansion also affects the way in which the hot valve contacts the seat. In valve and valve seat reconditioning, the valve is often ground with a face angle 1 degree less than the seat angle to compensate for the change in hot seating. This angle is called an interference angle. It makes a positive seal at the combustion chamber edge of the seat when the engine is first started after a valve job.
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As the valve seats are resurfaced, their widths increase. The resurfaced seats must be narrowed to make the seat width correct and to position the seat properly on the valve face. The normal automotive engine cylinder head valve seat is from 1/16 to 3/32 in. (1.5 to 2.5 mm) wide. There should be at least 1/32 in. (0.8 mm) of the ground valve face extending above the seat, called overhang. Some manufacturers recommend having the valve seat contact the middle of the valve face. In all cases, the valve seat width and the contact with the valve face match the manufacturer’s specifications. SEE FIGURE 31–26.
THREE-ANGLE VALVE JOB
A three-angle valve job means that the valve seats are ground three times.
The first angle is the angle of the valve seat specified by the vehicle manufacturer, usually 45 degrees.
The second angle uses a 60-degree stone or cutter to remove material right below the valve seat to increase flow in or out of the combustion chamber. This angle is called the throating angle. SEE FIGURE 31–27.
The third angle uses a 30-degree stone or cutter to smooth the transition between the valve seat and the cylinder head, again to increase flow in or out of the combustion chamber. This angle is called the topping angle. SEE FIGURE 31–28.
1/32” OVERHANG
1/32” MARGIN VALVE FACE ANGLE 45°
VALVE SEAT ANGLE 45°
TOP NARROWING ANGLE 30°
BOTTOM NARROWING ANGLE 60°
CONTACT PATCH
SEAT WIDTH AND PROPER LOCATION ON VALVE
FIGURE 31–29 A typical three-angle valve job using 30-, 45-, and 60-degree stones or cutters.
FIGURE 31–26 The seat must contact evenly around the valve face. For good service life, both margin and overhang should be at least 1/32 in. (0.8 mm).
“THROATING” STONE
VALVE SEAT
60°
VALVE SEAT CUTTER VALVE GUIDE PILOT
VALVE SEAT
FIGURE 31–27 Grinding a 60-degree angle removes metal from the bottom to raise and narrow the seat.
“TOPPING” STONE
FIGURE 31–30 A valve guide pilot being used to support a valve seat cutter.
VALVE GUIDE PILOTS TYPES OF PILOTS Valve seat reconditioning equipment uses a pilot in the valve guide to align the stone holder or cutter in the exact same location as the valve stem. This ensures accurate valve seatto-valve face sealing. Two types of pilots used include:
30°
VALVE SEAT
SEE FIGURE 31–30.
FIGURE 31–28 Grinding a 30-degree angle removes metal from the top to lower and narrow the seat. The three stones or cutters can be used in combination to create the desired seat width and where it contacts the face of the valve. The 60-degree throating stone will rise and narrow the seat. The 45-degree stone will widen the seat, and the 30-degree stone will lower and narrow the seat. SEE FIGURE 31–29.
Tapered pilots locate themselves in the least worn section of the guide. They are made in standard sizes and in oversize increments of 0.001 in., usually up to 0.004 in. OS. The largest pilot that will fit into the guide is used for valve seat reconditioning. This type of pilot restores the seat to be as close to the original position as possible when used with worn valve guides. Expandable pilots used with seating equipment are of two types. One type of adjustable pilot expands in the center of the guide to fit like a tapered pilot. The other expands to contact the ends of the guide where there has been the greatest wear. The valve itself will align in the same way as the pilot.
NOTE: If the guide is not reconditioned, the valve will match the seat when an expandable pilot is used. The pilot and guide should be thoroughly cleaned.
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VALVE SEAT GRINDING STONES TYPES OF STONES
Three basic types of grinding stones are
used. All are used dry.
A roughing stone is used to rapidly remove large amounts of seat metal. This would be necessary on a badly pitted seat or when installing new valve seat inserts. The roughing stone is sometimes called a seat forming stone.
After the seat forming stone, a finishing stone is used to put the proper finish on the seat. The finishing stone is also used to recondition cast-iron seats that are only slightly worn.
Hard seat stones are used on hard Stellite® exhaust seat inserts.
FIGURE 31–31 Checking valve seat concentricity using a dial indicator.
NOTE: Stellite® is a nonmagnetic hard alloy used for valve seats in heavy-duty applications.
Each time a stone is placed on a holder
At the beginning of each valve job
Any time the stone is not cutting smoothly and cleanly while grinding valve seats
GRINDING THE VALVE SEAT
01
01
FIGURE 31–32 Typical dial indicator type of micrometer for measuring valve seat concentricity.
STEP 5
The holder and stone should be lifted from the seat between each grinding burst to check the condition of the seat. The finished seat should be bright and smooth across the entire surface, with no pits or roughness remaining. Some of the induction hardness from the exhaust valve seat may extend over into the intake seat. It may be necessary to apply a slight pressure on the driver toward the hardened spot to form a concentric seat.
STEP 6
Check the seat with a dial indicator gauge to make sure that it is concentric within 0.002 in. (0.05 mm) before the seat is finished. The dial gauge measurement of the valve seat is very important. The maximum acceptable variation is 0.002 in., called the total indicator runout (TIR) of the valve seat. SEE FIGURES 31–31 AND 31–32.
The typical procedure includes
the following steps. STEP 1
The valve seat should be cleaned before grinding. This keeps the grinding dust from filling the grinding stone.
STEP 2
The pilot is then placed in the valve guide. A drop of oil is placed on the end of the pilot to lubricate the holder.
STEP 3
The holder, with the dressed grinding stone, is placed over the pilot. The driver should be supported so that no driver weight is on the holder. This allows the stone abrasive and the metal chips to fly out from between the stone and seat to give fast, smooth grinding.
STEP 4
Grinding is done in short bursts, such as two to three seconds each burst. Check to see if the seat is properly ground at the end of each burst. This procedure helps prevent the seat from being ground too deep.
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5
DRESSING THE GRINDING STONE The selected grinding stone is installed on the stone holder. The holder and grinding stone assembly is rotated with the driver. The diamond is adjusted so that it just touches the stone face. The diamond dressing tool is moved slowly across the face of the spinning stone, taking a very light cut. Dressing the stone in this way will give it a clean, sharp cutting surface. It is necessary to redress the stone at the following times.
5
0
The stone diameter and face angle must be correct. The diameter of the stone must be larger than the valve head, but it must be small enough that it does not contact the edge of the combustion chamber. The angle of the grinding surface of the stone must be correct for the seat. When an interference angle is used with reground valves, it is common practice to use a seat with the standard seat angle. The interference angle is ground on the valve face. In some cases, such as with an aluminized valve, the valve has the standard angle and the seat is ground to give the interference angle. The required seat angle must be determined before the seat grinding stone is dressed.
NARROWING THE VALVE SEAT
The valve seat becomes wider as it is ground. It is therefore necessary to narrow the seat so that it will contact the valve properly. The seat is topped with
CARBIDE CUTTERS
FACE OF VALVE
FIGURE 31–34 A cutter is used to remove metal and form the valve seat angles. MARGIN OF VALVE
CONTACT WIDTH WITH VALVE SEAT
FIGURE 31–33 After the valve face and the valve seat are ground (reconditioned), lapping compound is used to smooth the contact area between the two mating surfaces. Notice that the contact is toward the top of the face. For maximum life, the contact should be in the middle of the face. a grinding stone dressed to 15 degrees less than the seat angle. Therefore, use:
A 30-degree stone to narrow a 45-degree seat angle
A 15-degree stone for a 30-degree seat angle
Topping lowers the top edge of the seat. The amount of topping required can best be checked by measuring the maximum valve face diameter using dividers. The dividers are then adjusted to a setting 1/16 in. smaller to give the minimum valve face overhang. The seat is measured and then topped with short grinding bursts, as required, to equal the diameter set on the dividers. The seat width is then measured. If it is too wide, the seat must be throated with a stone with a 60-degree angle. This removes metal from the port side of the seat, raising the lower edge of the seat. Generally accepted seat widths are as follows:
For intake valves: 1/16 in. or 0.0625 in. (about the thickness of a nickel) (1.5 mm)
For exhaust valves: 3/32 in. or 0.0938 in. (about the thickness of a dime and a nickel together) (2.4 mm)
The completed seat must be checked with the valve that is to be used on the seat. This can be done using lapping compound or by marking across the valve face at four or five places with a felt-tip marker. The valve is then inserted in the guide so that the valve face contacts the seat. The valve is rotated 20 to 30 degrees and then removed. The location of the seat contact on the valve is observed where the felt-tip marking has been rubbed off from the valve. Valve seating can be seen in FIGURE 31–33. Valve seat grinding is complete when each of the valve seats has been properly ground, topped, and throated. To summarize:
Using a 30-degree topping stone (for a 45-degree seat) lowers the upper outer edge and narrows the seat. Using a 60-degree throating stone raises the lower inner edge and narrows the seat. Using a 45-degree stone widens the seat.
VALVE SEAT CUTTERS Some vehicle manufacturer and automotive service technicians recommend the use of valve seat cutters rather than valve seat grinders. SEE FIGURE 31–34. The valve seats can be reconditioned to commercial standards in much less time when using the cutters rather than the grinders. The advantages of using a seat cutter compared to a grinding stone include:
A number of cutting blades are secured at the correct seat angle in the cutting head of this valve seat reconditioning tool.
The cutter angle usually includes the interference angle so that new valves with standard valve face angles can be used without grinding the new valve face.
The cutters do not require dressing as stones do.
The cutter is rotated by hand or by using a special speed reduction motor. Only metal chips are produced.
The finished seat is checked for concentricity and fit against the valve face.
CAUTION: A cutter should only be rotated clockwise. If a cutter is rotated counterclockwise, damage to the cutting surfaces ruins the cutter.
VALVE SEAT TESTING PURPOSE After the valves have been refaced and the guides and valve seats have been resurfaced, the valves should be inspected for proper sealing and to ensure that the valve seat is concentric with the valve face. METHODS
Following are methods often used to check valve face-to-seat concentricity and valve seating. 1. Vacuum testing can be done by applying vacuum to the intake and/or exhaust port using a tight rubber seal and a vacuum pump. A good valve face-to-seat seal is indicated by maintaining at least 28 in. Hg of vacuum. This method also tests for leakage around the valve guides. Put some engine oil around the guides; if vacuum increases, valve guides may have excessive clearance. 2. The ports or chamber can be filled with mineral spirits or some other suitable fluid. A good seal should not leak fluid for at least 45 seconds. 3. Valve seating can be checked by applying air pressure to the combustion chamber and checking for air leakage past the valve seat.
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ALUMINUM CYLINDER HEAD VALVE GUIDE INSERT
FIGURE 31–36 Insert valve seats are rings of metal driven into the head.
VALVE SEAT
Damaged integral valve seats must be counterbored to make a place for the new insert seat.
INSERT SEAT REMOVAL METHODS
The old insert seat is
removed by one of several methods. FIGURE 31–35 All aluminum cylinder heads use valve seat inserts. If an integral valve seat (cast-iron head) is worn, it can be replaced with a replacement valve seat by machining a pocket (counterbore) to make a place for the new insert seat.
A small pry bar can be used to snap the seat from the counterbore.
It is sometimes easier to do this if the old seat is drilled to weaken it. Be careful not to drill into the head material.
Sometimes, an expandable hook-type puller is used to remove the seat insert. See the Tech Tip, “The MIG Welder Seat Removal Trick.” The seat counterbore must be cleaned before the new, oversize seat is installed. The replacement inserts have a 0.002 to 0.003 in. (0.05 to 0.07 mm) interference fit in the counterbore. The counterbores are cleaned and properly sized, using the same equipment described in the following paragraph for installing replacement seats in place of faulty integral valve seats.
TECH TIP The MIG Welder Seat Removal Trick A quick and easy method to remove insert valve seats is to use a metal inert gas (MIG) welder, also called a gas metal arc welder (GMAW). After the valve has been removed, use the MIG welder and lay a welding bead around the seat area of the insert. As the welder cools, it shrinks and allows the insert to be easily removed from the cylinder head. The weld bead also provides a surface that can be used to pry the seat from the cylinder head.
4. The valves can be lapped using valve grinding compound and looking at the “parting line” between the valve face on the valve and the valve seat in the cylinder head.
VALVE SEAT REPLACEMENT PURPOSE
Valve seats need to be replaced if they are cracked or if they are burned or eroded too much to be reground. SEE FIGURE 31–35. It may not be possible to determine whether a valve seat needs to be replaced before an attempt is made to recondition the valve seat. Valve seat replacement is accomplished by using a pilot in the valve guide. This means that the valve guide must be reconditioned before the seat can be replaced.
Damaged insert valve seats are removed and the seat counterbore is cleaned to accept a new oversize seat insert.
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TYPES OF VALVE SEATS
If an insert is being replaced, the new insert must be of the same type of material as the original insert or better. Insert exhaust valve seats operate at temperatures that are 100°F to 150°F (56°C to 83°C) hotter than those of integral seats up to 900°F (480°C). Upgraded valve and valve seat materials are required to give the same service life as that of the original seats. Removable valve seats are available in different materials, including:
Cast iron
Stainless steel
Nickel cobalt
Powdered metal (PM)
SEE FIGURE 31–36.
REPLACING AN INTEGRAL VALVE SEAT A counterbore cutting tool is selected that will cut the correct diameter for the outside of the insert. The diameter of the bore is smaller than the outside diameter of the seat insert. The procedure usually includes the following steps. STEP 1
The cutting tool is positioned securely in the tool holder so that it will cut the counterbore at the correct diameter.
STEP 2
The tool holder is attached to the size of pilot that fits the valve guide. The tool holder feed mechanism is screwed together so that it has enough threads to properly feed the cutter into the head. This assembly is placed in the valve guide so that the cutting tool rests on the seat that is to be removed.
VALVE STEM HEIGHT
TECH TIP Use the Recommended Specifications A technician replaced valve seat inserts in an aluminum cylinder head. The factory specification called for a 0.002 in. interference fit (the insert should be 0.002 in. larger in diameter than the seat pocket in the cylinder head). Shortly after the engine was started, the seat fell out, ruining the engine. The technician should have used the interference fit specification supplied with the replacement seat insert. Interference fit specifications depend on the type of material used to make the insert. Some inserts for aluminum heads require as much as 0.007 in. interference fit. Always refer to the specification from the manufacturer of the valve inserts when replacing valve seats in aluminum cylinder heads.
STEP 3
The new insert is placed between the support fixture and the stop ring. The stop ring is adjusted against the new insert so that cutting will stop when the counterbore reaches the depth of the new insert.
STEP 4
The boring tool is turned by hand or with a reduction gear motor drive. It cuts until the stop ring reaches the fixture.
STEP 5
The support fixture and the tool holder are removed. The pilot and the correct size of adapter are placed on the driving tool.
STEP 6
The seats should be cooled with dry ice to cause them to shrink. Each insert should be left in the dry ice until it is to be installed. This will allow it to be installed with little chance of metal being sheared from the counterbore. Sheared chips could become jammed under the insert, keeping it from seating properly. The chilled seat is placed on the counterbore.
STEP 7
The driver with a pilot is then quickly placed in the valve guide so that the seat will be driven squarely into the counterbore. The driver is hit with a heavy hammer to seat the insert.
STEP 8
Heavy blows are used to start the insert, and lighter blows are used as the seat reaches the bottom of the counterbore.
STEP 9
The installed valve seat insert is peened in place by running a peening tool around the metal on the outside of the seat. The peened metal is slightly displaced over the edge of the insert to help hold it in place.
VALVE STEM HEIGHT DEFINITION
Valve stem height is the distance the valve stem is above the spring seat. Valve stem height is a different measurement from installed height. SEE FIGURE 31–37.
Valve stem height is important to maintain for all engines, but especially for overhead camshaft engines.
When the valve seat and the valve face are ground, the valve stem extends deeper into the combustion chamber and extends higher or farther into the cylinder head.
The valve is put in the head, and the length from the tip to the valve spring seat is measured.
FIGURE 31–37 Valve stem height is measured from the spring seat to the tip of the valve after the valve seat and valve face have been refinished. If the valve stem height is too high, up to 0.02 in. can be ground from the tips of most valves.
The tip is ground to shorten the valve stem length to compensate for the valve face and seat grinding.
The valve will not close if the valve tip extends too far from the valve guide on engines that have hydraulic lifters and nonadjustable rocker arms.
If the valve is too long, the tip may be ground by as much as 0.02 in. (0.5 mm) to reduce its length. If more grinding is required, the valve must be replaced. If it is too short, the valve face or seat may be reground, within limits, to allow the valve to seat deeper.
Where excessive valve face and seat grinding has been done, shims can be placed under the rocker shaft on some engines as a repair to provide correct hydraulic lifter plunger centering. These shims must have the required lubrication holes to allow oil to enter the shaft.
INSTALLED HEIGHT DEFINITION
Installed height is the distance between the valve spring seat and the underside of the valve spring retainer. When the valves and/or valve seats have been machined, the valve projects farther than before on the rocker arm side of the head. The valve face is slightly recessed into the combustion chamber side of the head. The valve spring tension is, therefore, reduced because the spring is not as compressed as it was originally.
CORRECTING INSTALLED HEIGHT To restore original valve spring tension, special valve spring spacers, inserts, or shims are installed under the valve springs. These shims are usually called valve spring inserts (VSI). Valve spring inserts are generally available in three different thicknesses.
0.015 in. (0.38 mm). Used for balancing valve spring pressure
0.03 in. (0.75 mm). Generally used for new springs on cylinder heads that have had the valve seats ground and valves refaced
0.06 in. (1.5 mm). Necessary to bring assembled height to specifications (These thicker inserts may be required if the seats have been resurfaced more than once.)
STEP 1
To determine the exact thickness of insert to install, measure the valve spring installed height. SEE FIGURE 31–38.
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SPRING RETAINER
STEM HEIGHT
INSTALLED HEIGHT
AIR–FUEL MIXTURE CHARGE
VACUUM ON INTAKE
SPRING SEAT
FIGURE 31–38 Installed height is determined by measuring the distance from the spring seat to the bottom of the valve spring retainer.
FIGURE 31–40 Engine vacuum can draw oil past the valve guides and into the combustion chamber. The use of valve stem seals limits the amount of oil that is drawn into the engine. If the seals are defective, excessive blue (oil) smoke is most often observed during engine start-up.
VALVE GUIDE
VALVE STEM
VALVE SPRING INSERT (SHIM)
VALVE STEM SEAL
VACUUM
FIGURE 31–39 Valve spring inserts are used to restore proper installed height. STEP 2
If the installed height is greater than specifications, select the valve spring insert (shim) that brings the installed height to within specifications. Be sure to install the valve spring inserts with the grooves facing toward the cylinder head. These are used to allow air to flow between the cylinder and the insert to help insulate the valve springs. Most inserts are labeled with the message, “This Side Up,” which means toward the valve spring. SEE FIGURE 31–39.
CAUTION: Do not use more than one valve spring insert. If the correct installed height cannot be achieved using one insert, replace the valve seat to restore the proper installed height.
FIGURE 31–41 Engine oil can also be drawn past the exhaust valve guide because of a small vacuum created by the flow of exhaust gases. Any oil drawn past the guide would simply be forced out through the exhaust system and not enter the engine. Some engine manufacturers do not use valve stem seals on the exhaust valves.
TYPES OF VALVE STEM SEALS
VALVE STEM SEALS PURPOSE AND FUNCTION
Leakage past the valve guides is a major oil consumption problem in any overhead valve or overhead cam engine. A high vacuum exists in the intake port, as shown in FIGURE 31–40. Most engine manufacturers use valve stem seals on the exhaust valve, because a weak vacuum in the exhaust port area can draw oil into the exhaust stream, as illustrated in FIGURE 31–41. Valve stem seals are used on overhead valve engines to control the amount of oil used to lubricate the valve stem as it moves in the guide. The stem and guide will scuff if they do not have enough oil. Too much oil will cause excessive oil consumption and will cause heavy carbon deposits to build up on the spark plug nose and on the valves.
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The types of valve stem
seals include the following:
The umbrella valve stem seal holds tightly on the valve stem and moves up and down with the valve. Any oil that spills off the rocker arms is deflected out over the valve guide, much as water is deflected over an umbrella. As a result, umbrella valve stem seals are often called deflector valve stem seals. SEE FIGURE 31–42. The O-ring valve stem seal used on Chevrolet engines keeps oil from leaking between the valve stem and valve spring retainer. The oil is deflected over the retainer and shield. The assembly controls oil like an umbrella-type oil seal. Both types of valve stem seals allow only the correct amount of oil to reach the valve guide to lubricate the valve stem. The rest of the oil flows back to the oil pan. SEE FIGURE 31–43. Positive valve stem seals hold tightly around the valve guide, and the valve stem moves through the seal. The Teflon® wiping ring wipes the excess oil from the valve stem. SEE FIGURES 31–44 AND 31–45.
RUBBER AND TEFLON ® SEAL
VALVE STEMS
ALL TEFLON ® SEAL
UMBRELLA SEALS
KEEPERS
RETAINER
VALVE STEM
VALVE STEM
UMBRELLA SEAL
SPRING SNAP RING RUBBER JACKET VALVE GUIDE
FIGURE 31–42 Umbrella seals install over the valve stems and cover the guide.
LOCKS CAP SEAL SHIELD SPRING DAMPER
TEFLON ® INSERT
FIGURE 31–44 Positive valve stem seals are the most effective type because they remain stationary on the valve guide and wipe the oil from the stem as the valve moves up and down.
SQUARE-SECTION RING VALVE SEAL
DEFLECTOR OR SHIELD VALVE GUIDE
FIGURE 31–43 A small square cut O-ring is installed under the retainer in a groove in the valve under the groove(s) used for the keepers (locks).
TECH TIP Purchase Engine Parts from a Known Manufacturer It is interesting to note that an automotive service technician cannot tell the difference between these synthetic rubber valve stem seals if they have come out of the same mold for the same engine. Often suppliers that package gasket sets for sale at a low price will include low-temperature Nitrile, even when the engine needs higher-temperature polyacrylate. The best chances of getting the correct valve stem seal material for an engine is to purchase gaskets and seals packaged by a major brand gasket company.
SEAT INSERT
FIGURE 31–45 The positive valve stem seal is installed on the valve guide.
VALVE SEAL MATERIALS
Valve stem seals are made from many different types of materials. They may be made from nylon or Teflon, but most valve stem seals are made from synthetic rubber. Three types of synthetic rubbers are in common use.
Nitrile (Nitril)
Polyacrylate
Viton
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FIGURE 31–46 An assortment of shapes, colors, and materials of positive valve stem seals.
HEAVY-DUTY VALVE SPRING COMPRESSOR
VALVE STEM SEAL
VALVE SPRING SEAT
FIGURE 31–48 Assembling a race engine using a heavy-duty valve spring compressor.
ALUMINUM CYLINDER HEAD
VALVE SPRING SEAT
FIGURE 31–47 A metal valve spring seat must be used between the valve spring and the aluminum cylinder head. Many Chrysler aluminum cylinder heads use a combination valve spring seat and valve stem seal.
Nitrile is the oldest valve stem seal material. It has a low cost and a low useful temperature. Engine temperatures have increased with increased emission controls and improved efficiencies, which made it necessary to use premium polyacrylate, even with its higher cost. In many cases, it is being retrofit to the older engines because it will last much longer than Nitrile. Diesel engines and engines used for racing, heavy trucks, and trailer towing, along with turbocharging, operate at still higher temperatures. These engines may require expensive Viton valve stem seals that operate at higher temperatures. SEE FIGURE 31–46.
TECH TIP Check Before Bolting It On Using new assembled cylinder heads, whether aluminum or cast iron, is a popular engine buildup option. However, experience has shown that metal shavings and casting sand are often found inside the passages. Before bolting on these “ready to install” heads, disassemble them and clean all passages. Often machine shavings are found under the valves. If this debris were to get into the engine, the results would be extreme wear or damage to the pistons, rings, block, and bearings. This cleaning may take several hours, but how much is your engine worth?
STEP 3
Umbrella and positive valve stem seals are installed. Push umbrella seals down until they touch the valve guide. Use a plastic sleeve over the tip of the valve when installing positive seals to prevent damage to the seal lip. Make sure that the positive seal is fully seated on the valve guide and that it is square.
STEP 4
Hold the valve against the seat as the valve spring seat or insert, valve spring, valve seal, and retainer are placed over the valve stem. One end of the valve spring compressor pushes on the retainer to compress the spring. Install the valve spring seat if assembling an aluminum head. SEE FIGURE 31–47.
STEP 5
The O-ring type of valve stem seal, if used, is installed in the lower groove. The valve keepers are installed while the valve spring is compressed. Using grease helps to keep them attached to the valve stem as the valve spring compressor is released.
STEP 6
Release the valve spring compressor slowly and carefully while making sure that the valve keepers seat properly between the valve stem grooves and the retainer. SEE FIGURE 31–48.
INSTALLING THE VALVES PROCEDURE
Assembling a cylinder head includes the following
steps. STEP 1
Clean the reconditioned cylinder head thoroughly with soap and water to wash away any remaining grit and metal shavings from the valve grinding operation.
STEP 2
Valves are assembled in the head, one at a time. The valve guide and stem are given a liberal coating of engine oil, and the valve is installed in its guide.
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INSTALLING A NEW VALVE SEAT
1
After the valve guide has been replaced or checked for being within specification, insert a pilot into the valve guide.
2
Level the bubble on the pilot by moving the cylinder head, which is clamped to a seat/guide machine.
3
Select the proper guide for the application. Consult guide manufacturer’s literature for recommendations.
4
Select the correct cutter and check that the cutting bits are sharp.
5
Carefully measure the exact outside diameter (O.D.) of the valve seat.
6
Adjust the depth of the cutter bit to achieve the specified interference fit for the valve seat.
CONTINUED
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INSTALLING A NEW VALVE SEAT
(CONTINUED)
7
Install the pilot into the valve guide to support the seat cutter.
8
9
Adjust the depth of cut, using the new valve seat to set it to the same depth as the thickness of the seat.
10
With the cylinder head still firmly attached to the seat and guide machine, start the cutter motor and cut the head until it reaches the stop.
12
Place the chilled valve seat over the pilot being sure that the chamfer is facing toward the head as shown.
11 312
The finish cut valve seat pocket. Be sure to use a vacuum to remove all of the metal shavings from the cutting operation.
CHAPTER 3 1
Install the seat cutter onto the pilot.
STEP BY STEP
13
Install the correct size driver onto the valve seat.
15
A new valve seat is now ready to be machined or cut.
14
Using the air hammer or press, press the valve seat into the valve pocket.
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REVIEW QUESTIONS 1. What is the procedure for grinding valves?
4. Describe the difference between cutting and grinding valve seats.
2. When is the valve tip ground? How do you know how much to remove from the tip?
5. How is a valve seat insert installed?
3. What is an interference angle between the valve and the seat?
6. How are the correct valve spring inserts (shims) selected and why are they used?
CHAPTER QUIZ 1. In a normally operating engine, intake and exhaust valves are opened by a cam and closed by the ______________. a. Rocker arms or cam follower c. Lifters (tappets) b. Valve spring d. Valve guide and/or pushrod 2. If an interference angle is machined on a valve or seat, this angle is usually ______________. a. 1 degree c. 1 to 3 degrees b. 0.005 degree d. 0.5 to 0.75 degree 3. Never remove more material from the tip of a valve than ______________. a. 0.001 in. c. 0.02 in. b. 0.002 in. d. 0.05 in. 4. A valve should be discarded if the margin is less than ______________ after refacing. a. 0.001 in. c. 0.03 in. b. 0.006 in. d. 0.06 in. 5. A valve seat should be concentric to the valve guide to a maximum TIR of ______________. a. 0.006 in. c. 0.002 in. b. 0.004 in. d. 0.00015 in. 6. To lower and narrow a valve seat that has been cut at a 45-degree angle, use a cutter or stone of what angle? a. 60 degrees c. 30 degrees b. 45 degrees d. 15 degrees
chapter
32
7. Valve spring inserts (shims) are designed to ______________. a. Increase installed height of the valve b. Decrease installed height of the valve c. Adjust the correct valve spring installed height d. Decrease valve spring pressure to compensate for decreased installed height 8. The proper relationship between intake and exhaust valve diameter is ______________. a. Intake valve size is 85% of exhaust valve size b. Exhaust valve size is 85% of intake valve size c. Exhaust valve size is 38% of intake valve size d. Intake valve size is 45% of exhaust valve size 9. Dampers (damper springs) are used inside some valve springs to ______________. a. Prevent valve spring surge b. Keep the valve spring attached to the valve c. Decrease valve spring pressure d. Retain valve stem seals 10. Umbrella-type valve stem seals ______________. a. Fit tightly onto the valve guide b. Fit on the valve face to prevent combustion leaks c. Fit tightly onto the valve stem d. Lock under the valve retainer
CAMSHAFTS AND VALVE TRAINS
OBJECTIVES: After studying Chapter 32, the reader should be able to: • Prepare for the ASE Engine Repair (A1) certification test content area “B” (Cylinder Head and Valve Train Diagnosis and Repair). • Describe how the camshaft and valve train function. • Discuss valve train noise and its causes. • Explain how a hydraulic lifter works. • Describe the purpose and function of variable valve timing. KEY TERMS: Aerated 328 • Asymmetrical 320 • Bucket 323 • Cam chucking 319 • Cam follower 323 • Cam-in-block 315 • Camshaft bearings 315 • Camshaft duration 323 • Composite camshaft 315 • Double roller chain 318 • Dual overhead camshaft (DOHC) 315 • Finger follower 323 • Flat-link type 317 • Freewheeling engine 318 • Hydraulic lash adjusters (HLA) 323 • Hydraulic valve lifter 327 • Interference engine 318 • Lobe 315 • Lobe centers 324 • Lobe displacement angle (LDA) 324 • Lobe lift 319 • Lobe separation 324 • Lobe spread 324 • Morse type 317 • Oil control valve (OCV) 330 • Overhead camshaft (OHC) 315 • Overhead valve (OHV) 315 • Pump-up 327 • Ramp 327 • Roller chain type 318 • Scavenging 330 • Seat duration 330 • Silent chain type 317 • Single overhead camshaft (SOHC) 315 • Solid valve lifter 327 • Symmetrical 320 • Thrust plate 319 • Total indicator runout (TIR) 329 • Valve cam phases (VCP) 332 • Valve (camshaft) overlap 324 • Valve float 327 • Valve lash 327 • Variable valve timing (VVT) 331 • Variable valve timing and lift electronic control (VTEC) 334
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CAMSHAFT BEARING JOURNAL
DISTRIBUTOR SHAFT
LOBE
FIGURE 32–1 This high-performance camshaft has a lobe that opens the valve quickly and keeps it open for a long time.
CAMSHAFT
OIL PUMP
FIGURE 32–2 In many engines, the camshaft drives the distributor and the oil pump through a shaft from the end of the distributor.
PURPOSE AND FUNCTION
The major function of a camshaft is to open the valves. Camshafts have eccentric shapes called lobes that open the valve against the force of the valve springs. The valve spring closes the valve when the camshaft rotates off of the lobe. The camshaft lobe changes rotary motion (camshaft) to linear motion (valves). Cam shape or contour is the major factor in determining the operating characteristics of the engine.
OPERATION
The camshaft is driven by:
Timing gears
Timing chains
Timing belts
The gear or sprocket on the camshaft has twice as many teeth, or notches, as the one on the crankshaft. This results in two crankshaft revolutions for each revolution of the camshaft. The camshaft turns at one-half the crankshaft speed in all four-stroke cycle engines. Cam lobe shape has more control over engine performance characteristics than any other single engine part. Engines identical in every way except cam lobe shape may have completely different operating characteristics and performance. SEE FIGURE 32–1. The camshaft may also operate the following:
Mechanical fuel pump (carburetor-equipped engines)
Oil pump
Distributor (if equipped)
SEE FIGURE 32–2.
CAMSHAFT LOCATION
There are two basic areas where the camshaft can be located in an engine.
In the engine block. This design is called the cam-in-block design. The camshaft is supported in the block by camshaft bearings and driven by the crankshaft with a gear or sprocket and chain drive. Engines with the cam located in the block are called pushrod or overhead valve (OHV) engines. SEE FIGURE 32–3. Overhead. Overhead camshafts are either belt or chain driven from the crankshaft and are located in the cylinder head(s). This arrangement is called overhead camshaft (OHC) design. If there is a single overhead camshaft for each bank of cylinders, the engine is classified as a single overhead
FIGURE 32–3 The camshaft rides on bearings inside the engine block above the crankshaft on a typical cam-in-block engine.
camshaft (SOHC) engine design. If an engine uses two overhead camshafts per bank of cylinders, this type of engine design is called a dual overhead camshaft (DOHC).
CAMSHAFT DESIGN CONSTRUCTION The camshaft is usually a one-piece casting from chilled cast iron for many production engines that includes:
Lobes
Bearing journals
Accessory drive gear
SEE FIGURE 32–4. Other types of camshaft construction include:
Forged steel (often used in diesel engines)
Steel machined from a solid billet
Composite camshafts, which use a lightweight tubular shaft with hardened steel lobes press-fitted over the shaft (The
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ECCENTRIC (FOR FUEL PUMP IF USED)
OIL HOLES
REAR BEARING CAMS
OIL GROOVE
KEYWAY
TOPPED HOLE GEAR FIT OIL HOLES
FRONT BEARING
DRIVE GEAR FOR DISTRIBUTOR (OIL PUMP)
FIGURE 32–4 Parts of a cam and camshaft terms (nomenclature).
CAM LOBES
FIGURE 32–6 Worn camshaft with two lobes worn to the point of being almost round.
HOLLOW STEEL TUBE
FIGURE 32–5 A composite camshaft is lightweight and yet flexible, because the hollow tube can absorb twisting forces and the lobes are hard enough to withstand the forces involved in opening valves. actual production of these camshafts involves placing the lobes over the tube shaft in the correct position. A steel ball is then drawn through the hollow steel tube, expanding the tube and securely locking the cam lobes in position. SEE FIGURE 32–5.)
CAMSHAFT BEARING JOURNALS
On pushrod engines, camshaft-bearing journals must be larger than the cam lobe so that the camshaft can be installed in the engine through the cam bearings. Some overhead cam engines have bearing caps on the cam bearings. These cams can have large cam lobes with small bearing journals. Cam bearings on some engines are progressively smaller from the front journal to the rear. Other engines use the same size of camshaft bearing on all the journals.
HARDNESS Older automotive camshafts were used with flat or convex-faced lifters and made from hardened alloy cast iron. It resists wear and provides the required strength. The very hardness of the camshaft causes it to be susceptible to chipping as the result of edge loading or careless handling. Cast-iron camshafts have about the same hardness throughout. If reground, they should be recoated with a phosphate coating. Steel camshafts are usually constructed from SAE 4160 or 4180 steel and are usually induction hardened. Induction hardening
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involves heating the camshaft to cherry red in an electric field (heating occurs by electrical induction). The heated camshaft is then dropped into oil. The rapid cooling hardens the surface. Camshafts can also be hardened by using the following methods.
Liquid nitriding, which hardens to 0.001 to 0.0015 in. thick
Gas nitriding, which hardens to 0.004 to 0.006 in. thick
Typical camshaft hardness should be 42 to 60 on the Rockwell “c” scale. NOTE: Rockwell is a type of hardness test, and the c represents the scale used. The higher the number, the harder the surface. The abbreviation Rc60, therefore, indicates Rockwell hardness of 60 as measured on the “c” scale. If this outer hardness wears off, the lobes of the camshaft are easily worn until they are almost completely rounded. SEE FIGURE 32–6.
CAMSHAFT LUBRICATION
Some engines transfer lubricating oil from the main oil gallery to the crankshaft around the camshaft journal or around the outside of the camshaft bearing. Cam bearing clearance is critical in these engines. If the clearance is too great, oil will leak out and the crankshaft bearings will not get enough oil. Other engines use drilled holes in the camshaft bearing journals to meter lubricating oil to the overhead rocker arm. Oil goes to the rocker arm each time the holes line up between the bearing oil gallery passage and the outlet passage to the rocker arm.
FUEL PUMP ECCENTRICS An eccentric cam lobe for the mechanical fuel pump is often cast as part of the camshaft used in older engines before fuel injection. SEE FIGURE 32–7. Some engines use a steel cup type of eccentric that is bolted to the front of the cam drive gear. This allows a damaged fuel pump eccentric to be replaced without replacing an entire camshaft.
DIAPHRAGM SPRING
ROCKER ARM
CAMSHAFT ECCENTRIC
CYLINDER BLOCK
PUMP BODY PUMP DIAPHRAGM
INLET CHECK VALVE INLET FITTING
FUEL CHAMBER
OUTLET CHECK VALVE PULSATOR DIAPHRAGM
FIGURE 32–7 The fuel pump rocker arm rides on the camshaft eccentric.
CAMSHAFT GEAR CRANKSHAFT GEAR
FIGURE 32–9 The larger camshaft gear is usually made from fiber and given a helical cut to help reduce noise. By making the camshaft gear twice as large as the crankshaft gear, the camshaft rotates one revolution for every two of the crankshaft.
FIGURE 32–8 A timing chain hydraulic tensioner.
CAMSHAFT DRIVES PURPOSE AND FUNCTION
The crankshaft drives the cam-
shaft with one of the following:
Timing gears
Sprockets and chains
Sprockets and timing belts
Timing chains often have tensioners (dampers) pressing on the unloaded side of the chain. The tensioner pad is a Nylatron molding that is filled with molybdenum disulfide to give it low friction. The tensioner is held against the chain by either a spring or hydraulic oil pressure. SEE FIGURE 32–8. The gears or sprockets are keyed to their shafts so that they can be installed in only one position. The gears and sprockets are then indexed together by marks on the gear teeth or chain links. However, some engines use a tolerance ring that locks the drive sprocket to the camshaft such as the Ford modular V-8s. In these engines, the drive sprocket should not be removed from the camshaft unless the specified procedures are followed. When the crankshaft and camshaft timing marks are properly lined up, the cam lobes are indexed to the crankshaft throws of each cylinder so that the valves will open and close correctly in relation to the piston position.
CAMSHAFT CHAIN DRIVES
The crankshaft gear or sprocket that drives the camshaft is usually made of sintered iron. When
FIGURE 32–10 A replacement silent chain and sprockets. The original camshaft sprocket was aluminum with nylon teeth to help control noise. This replacement set will not be noticeably louder than the original and should give the owner many thousands of miles of useful service.
gears are used on the camshaft, the teeth must be made from a soft material to help reduce noise. Usually, the whole gear is made of aluminum or fiber, especially in older engines. SEE FIGURE 32–9. When a chain and sprocket are used, the camshaft sprocket may be made of iron or it may have an aluminum hub with nylon teeth for noise reduction. Two types of timing chains are used. 1. The silent chain type (also known as a flat-link type, or Morse type for its original manufacturer) operates quietly but tends to stretch with use. The metal links themselves do not “stretch” but, instead, the pin bushings at each joint wear, which causes the chain to become longer. SEE FIGURES 32–10 AND 32–11.
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PRIMARY CHAIN
1/4" OK
1/2" REPLACE
FIGURE 32–11 The industry standard for when to replace a timing chain and gears is when 1/2 in. (13 mm) or more of slack is measured in the chain. However, it is best to replace the timing chain and gear anytime the camshaft is replaced or the engine is disassembled for repair or overhaul.
FIGURE 32–12 A replacement high-performance double roller chain. Even though a bit noisier than a flat-link chain, a roller chain does not stretch as much and will therefore be able to maintain accurate valve timing for a long time.
SECONDARY CHAIN
FIGURE 32–13 This dual overhead camshaft (DOHC) engine uses one chain from the crankshaft to the intake cam and a secondary chain to rotate the exhaust camshaft.
FIGURE 32–14 A timing belt failed when the teeth were sheared off. This belt failed at 88,000 miles because the owner failed to replace it at the recommended interval of 60,000 miles.
NOTE: When the timing chain stretches, the valve timing will be retarded and the engine will lack low-speed power. In some instances, the chain can wear through the timing chain cover and create an oil leak. 2. The roller chain type is noisier but operates with less friction and stretches less than the silent type of chain. If two chains are used side by side, this type of chain is called a double roller chain. SEE FIGURE 32–12. Some four-cam engines use a two-stage camshaft drive system:
Primary, from crankshaft to camshaft
Secondary, from one camshaft to another
SEE FIGURE 32–13.
CAMSHAFT BELT DRIVES
Many overhead camshaft engines use a timing belt rather than a chain. Cam drive belts are made from rubber and fabric and are often reinforced with fiberglass or Kevlar. The belt sprocket teeth are square-cut or cogged. Drive belts and sprockets reduce weight compared to a chain drive and require no lubrication with reduced noise. However, the belt requires periodic
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FIGURE 32–15 This timing belt broke because an oil leak from one of the camshaft seals caused oil to get into and weaken the belt. Most experts recommend replacing all engine seals in the front of the engine anytime a timing belt is replaced. If the timing belt travels over the water pump, the water pump should also be replaced as a precaution. replacement, usually every 60,000 miles (100,000 km) or longer in some vehicles. SEE FIGURES 32–14 AND 32–15. Unless the engine is freewheeling, the piston can hit the valves if the belt breaks. A freewheeling engine is one that causes no internal damage if the camshaft drive belt breaks when the engine is running. An interference engine, however, will cause some of the valves that are open to hit the pistons, causing major engine damage. SEE FIGURES 32–16 AND 32–17.
FREEWHEELING ENGINE DESIGN
INTERFERENCE ENGINE DESIGN
NO VALVE/PISTON INTERFERENCE
VALVE/PISTON COLLISION
NOTE THAT THE LIFTER BORES ARE OFFSET TO ALLOW ROTATION.
ABOUT 0.002"
CLEARANCE
RIGHT
FIGURE 32–16 Many engines are of the interference design. If the timing belt (or chain) breaks, the piston still moves up and down in the cylinder while the valves remain stationary. With a freewheeling design, nothing is damaged, but in an interference engine, the valves are often bent.
c
NOTE: THE TAPER IS USUALLY BETWEEN 0.0007" TO 0.002".
FIGURE 32–18 The slight angle and the curve on the bottom of a flat bottom lifter cause the lifter and the pushrod to rotate during normal operation.
BENT VALVES
LOBE LIFT
FIGURE 32–17 A head from a Mercedes showing bent valves when the timing chain stretched and skipped over the crankshaft sprocket. When this happened, the piston kept moving and bent the valves.
CAMSHAFT MOVEMENT REASONS CAMSHAFTS MOVE
On engines equipped with flat bottom lifters, as the camshaft lobe pushes the lifter upward against the valve spring force, a backward twisting force is developed on the camshaft. After the lobe goes past its high point, the lifter moves down the backside of the lobe. This makes a forward twisting force. This action produces an alternating torsion force forward, then backward, at each cam lobe. The number of cam lobes on the shaft multiplies this alternating torsion force. Cam chucking is the movement of the camshaft lengthwise in the engine during operation. Each camshaft must have some means to control the shaft end thrust. One method is to use a thrust plate between the camshaft drive gear or sprocket and a flange on the camshaft. A thrust plate is attached to the engine block with cap screws. In a few camshafts, a button, spring, or retainer that contacts the timing cover limits forward motion of the camshaft.
FIGURE 32–19 The lobe lift is the amount the cam lobe lifts the lifter. The blue circle is called the base circle. Because the rocker arm adds to this amount, the entire valve train has to be considered when selecting a camshaft that has the desired lift and duration.
WHY FLAT-BOTTOM LIFTERS ROTATE
Valve trains that use flat bottom lifters use a spherical (curved) lifter face that slides against the cam lobe. This produces a surface on the lifter face that is slightly convex, by about 0.002 in. The lifter also contacts the lobe at a point that is slightly off center. This produces a small turning force on the lifter to cause some lifter rotation for even wear. In operation, there is a wide line of contact between the lifter and the high point of the cam lobe. SEE FIGURE 32–18. These are the highest loads that are produced in an engine. This surface is the most critical lubrication point in an engine.
CAMSHAFT LOBE LIFT The lobe lift of the cam is usually expressed in decimal inches and represents the distance that the valve lifter or follower is moved. The amount that the valve is lifted is determined by the lobe lift times the ratio of the rocker arm. SEE FIGURES 32–19 AND 32–20. The higher the lift of the camshaft lobe, the greater the amount of air and fuel that can enter the engine. The more air and fuel burned in an engine, the greater the power potential of the engine.
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NOSE
B
A
OPENING RAMP
CLOSING RAMP
LASH RAMP
HEEL
FIGURE 32–20 The ramps on the cam lobe allow the valves to be opened and closed quickly yet under control to avoid damaging valve train components, especially at high engine speeds.
FIGURE 32–21 A 1.5:1 ratio rocker arm means that dimension A is 1.5 times the length of dimension B. Therefore, if the pushrod is moved up 0.4 in. by the camshaft lobe, the valve will be pushed down (opened) 0.4 in. 1.5, or 0.6 in.
TECH TIP Best to Warn the Customer A technician replaced a timing chain and gears on a high mileage Chevrolet V-8. The repair was accomplished correctly, yet after starting, the engine burned an excessive amount of oil. Before the timing chain replacement, oil consumption was minimal. The replacement timing chain restored proper operation of the engine by restoring the proper cam and valve timing which increased engine vacuum. Increased vacuum can draw oil from the crankcase past worn piston rings and through worn valve guides during the intake stroke. Similar increased oil consumption problems occur if a valve job is performed on a high-mileage engine with worn piston rings and/or cylinders. To satisfy the owner of the vehicle, the technicians had to disassemble and refinish the cylinders and replace the piston rings. Therefore, all technicians should warn customers that increased oil usage might result from almost any engine repair to a high-mileage engine.
FIGURE 32–22 A high-performance aluminum roller rocker arm. Both the pivot and the tip that contacts the stem of the valve are equipped with rollers to help reduce friction for more power and better fuel economy.
ROCKER ARMS PURPOSE AND FUNCTION
The amount of lift of a camshaft is often different for the intake and exhaust valves.
If the specifications vary, the camshaft is called asymmetrical.
If the lift is the same, the cam is called symmetrical.
However, when the amount of lift increases, so do the forces on the camshaft and the rest of the valve train. Generally, a camshaft with a lift of over 0.5 in. (1.3 cm) is unsuitable for street operation except for use in engines that are over 400 in.3 (6 liters). The lift specifications at the valve face assume the use of the stock rocker arm ratio. If nonstock rocker arms with a higher ratio are installed (for example, 1.6:1 rockers replacing the stock 1.5:1 rocker arms), the lift at the valve is increased. Also, because the rocker arm rotation covers a greater distance at the pivot of the rocker arm, the rocker arm can hit the edge of the valve retainer.
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A rocker arm reverses the upward movement of the pushrod to produce a downward movement on the tip of the valve. Engine designers make good use of the rocker arm. It is designed to reduce the travel of the cam follower or lifter and pushrod while maintaining the required valve lift. This is done by using a rocker arm ratio usually of 1.5:1. For a given amount of lift on the pushrod, the valve will open to 1.5 times the cam lobe lift. This ratio allows the camshaft to be smaller, so the engine can be smaller. SEE FIGURE 32–21.
CAUTION: Using rocker arms with a higher ratio than stock can also cause the valve spring to compress too much and actually bind. Valve spring bind (coil bind) occurs when the valve spring is compressed to the point where there is no clearance in the spring. (It is completely compressed.) When coil bind occurs in a running engine, bent pushrods, broken rocker arms, or other valve train damage can result. SEE FIGURE 32–22.
ADJUSTMENT SCREW LOCKNUT
VALVE SPRING
EXHAUST VALVE
ROCKER ARM ROCKER ARM ROCKER SHAFT
A STUD VIEW “A”
CAMSHAFT CYLINDER HEAD INTAKE VALVE
FIGURE 32–23 Some engines today use rocker shafts to support rocker arms such as the V-6 engine with a single overhead camshaft located in the center of the cylinder head.
FIGURE 32–24 A typical stud-mounted rocker arm.
Rocker arms may be:
Cast
Forged
Stamped steel
Forged rocker arms are the strongest, but they require expensive manufacturing operations. Rocker arms may have bushings or bearings installed to reduce friction and increase durability. Cast rocker arms cost less to make and do not usually use bushings, but they do require several machining operations. They are not as strong as forged rocker arms but are satisfactory for passenger vehicle service. Stamped steel rocker arms are lightweight and cost effective.
SHAFT-MOUNTED ROCKER ARMS
On some overhead valve and most single overhead camshaft engines, the rocker arms are mounted on a shaft that runs the full length of the cylinder head. SEE FIGURE 32–23. Because the shaft provides a strong and stable platform for the rocker arms, shaft-mounted rocker arms work well, especially at high engine speeds. While most overhead camshaft engines that use rocker arm shafts do use an adjustable rocker arm, most OHV engines using rocker arm shafts have no provision for adjustment. Shaft-mounted rocker arms are lubricated through oil passages that travel from the block through the head and into the shaft, and then to the rocker arms.
PUSH ROD GUIDE PLATE
FIGURE 32–25 Pushrod guide plates are bolted to the head and help stabilize the valve train, especially at high engine speeds. BOLT
OIL DEFLECTOR
PEDESTAL
ROCKER ARM
STUD-MOUNTED ROCKER ARMS
Stud-mounted rockers are only found on overhead valve (OHV) engines and each rocker arm is attached to a stud that is pressed or threaded into the cylinder head. A ball on top of the rocker arm provides the bearing surface as the rocker arm pivots and is held in place and adjusted for valve clearance by a nut. While this design looks less stable than a shaft-mounted rocker, this design has proved to be reliable and is inexpensive to manufacture. The rocker arms receive lubricating oil under pressure through hollow pushrods. SEE FIGURE 32–24. Some engines use pushrod guide plates fastened to the head. SEE FIGURE 32–25.
PEDESTAL-MOUNTED ROCKER ARMS
Pedestal-mounted rocker arms are similar to stud-mounted rocker arms but do not use a stud and are used only in overhead valve engines. Two rocker arms are attached to and pivot on a pedestal attached to the cylinder head with one or two bolts. The pedestal is usually made from aluminum and the rocker arms are usually stamped steel, which is lightweight and nonadjustable. SEE FIGURE 32–26.
FIGURE 32–26 A pedestal-type rocker arm design that used one bolt for each rocker arm and is nonadjustable. If valve lash needs to be adjusted, different length pushrod(s) must be used.
?
FREQUENTLY ASKED QUESTION
Are the Valves Adjustable? If the stud has the same diameter for its whole length, the rockers are adjustable and the nut will be the “interference” type (lock-type nut). If the stud has a shoulder of a different diameter, the rockers are nonadjustable and the nut will not have interference threads.
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ROCKER ARM
PUSHROD
FIGURE 32–28 When the timing chain broke, the valves stopped moving up and down but the pistons kept moving and hit the valves causing the pushrods to bend.
LIFTER
CAMSHAFT
FIGURE 32–27 Overhead valve engines are also known as pushrod engines because of the long pushrod that extends from the lifter to the rocker arm.
TECH TIP
FIGURE 32–29 Hardened pushrods should be used in any engine that uses pushrod guides (plates). To determine if the pushrod is hardened, simply try to scratch the side of the pushrod with a pocketknife.
Rocker Arm Shafts Can Cause Sticking Valves TECH TIP
As oil oxidizes, it forms a varnish. Varnish buildup is particularly common on hot upper portions of the engine, such as rocker arm shafts. The varnish restricts clean oil from getting into and lubricating the rocker arms. The cam lobe can easily force the valves open, but the valve springs often do not exert enough force to fully close the valves. The result is an engine miss, which may be intermittent. Worn valve guides and/or weak valve springs can also cause occasional rough idle, uneven running, or an engine misfire.
Hollow Pushrod Dirt Many engine rebuilders and remanufacturers do not reuse old hollow pushrods. Dirt, carbon, and other debris are difficult to thoroughly clean from inside a hollow pushrod. When an engine is run with used pushrods, the trapped particles can be dislodged and ruin new bearings and other new engine parts. Therefore, for best results, consider purchasing new hollow pushrods instead of trying to clean and reuse the originals.
PUSHRODS TECH TIP
PURPOSE AND FUNCTION
Pushrods transfer the lifting motion of the valve train from the cam lobe and lifters to the rocker arms. SEE FIGURE 32–27.
TYPES OF PUSHRODS Pushrods are designed to be as light as possible and still maintain their strength. They may be either solid or hollow. If they are to be used as passages for oil to lubricate rocker arms, they must be hollow. Pushrods use a convex ball on the lower end that seats in the lifter. The rocker arm end is also a convex ball, unless there is an adjustment screw in the pushrod end of the rocker arm. In this case, the rocker arm end of the pushrod has a concave socket. It mates with the convex ball on the adjustment screw in the rocker arm. All pushrods should be rolled on a flat surface to check for straightness. SEE FIGURE 32–28.
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The Scratch Test All pushrods used with guide plates must be hardened on the sides and on the tips. To easily determine if a pushrod is hardened, simply use a sharp pocketknife to scrape the wall of the pushrod. A heat-treated pushrod will not scratch. SEE FIGURE 32–29.
The tolerance in the valve train allows for some machining of engine parts without the need to change pushrod length. However, if one or more of the following changes have been made to an engine, a different pushrod length may be necessary.
Block deck height machined
Cylinder head deck height machined
CAMSHAFT HYDRAULIC LIFTER HYDRAULIC ADJUSTER
LIFTER
OIL ENTERS HERE ROCKER ARM
VALVE STEM CONTACTS HERE
FIGURE 32–30 Hydraulic lifters may be built into bucket-type lifters on some overhead camshaft engines. CAM FOLLOWER
CAMSHAFT
HYDRAULIC LIFTER
CAMSHAFT
FIGURE 32–32 Hydraulic lash adjusters (HLA) are built into the rocker arm on some OHC engines. Sometimes hydraulic lash adjusters may not bleed down properly if the wrong viscosity (SAE rating) oil is used. FIGURE 32–31 The use of cam followers allows the use of hydraulic lifters with an overhead camshaft design.
Camshaft base circle size reduced
Valve length increased
Lifter design changed
OVERHEAD CAMSHAFT VALVE TRAINS TERMINOLOGY Overhead camshaft engines use several different types of valve opening designs. 1. One type opens the valves directly with a bucket. SEE FIGURE 32–30. 2. The second type uses a cam follower, also called a finger follower, that provides an opening ratio similar to that of a rocker arm. Finger followers open the valves by approximately 1 1/2 times the cam lift. The pivot point of the finger follower may have a mechanical adjustment or it may have an automatic hydraulic adjustment. SEE FIGURE 32–31.
3. A third type moves the rocker arm directly through a hydraulic lifter. 4. In the fourth design, some newer engines have the hydraulic adjustment in the rocker arm and are commonly called hydraulic lash adjusters (HLA). SEE FIGURE 32–32.
CAMSHAFT SPECIFICATIONS DURATION
Camshaft duration is the number of degrees of crankshaft (not camshaft) rotation for which a valve is lifted off the seat. The specification for duration can be expressed by several different methods, which must be considered when comparing one cam with another. The three most commonly used methods include: 1. Duration of valve opening at zero lash (clearance). If a hydraulic lifter is used, the lash is zero. If a solid lifter is used, this method of expression refers to the duration of the opening of the valve after the specified clearance (lash) between the rocker arm and the valve stem tip has been closed. 2. Duration at 0.05 in. lifter (tappet) lift. Because this specification method eliminates all valve lash clearances and compensates for lifter (tappet) styles, it is the preferred method to use when
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TDC
BDC
TDC
BDC
TDC
EXHAUST OPEN STARTING
INTAKE VALVE TO CLOSE OPENING
EXHAUST VALVE STARTING TO OPEN
EXHAUST
INTAKE VALVE OPENING
INTAKE OVERLAP
0°
180°
360°
540°
720°
CRANKSHAFT ROTATION
FIGURE 32–33 Graphic representation of a typical camshaft showing the relationship between the intake and exhaust valves. The shaded area represents the overlap period of 100 degrees. comparing one camshaft with another. Another method used to specify duration of some factory camshafts is to specify crankshaft duration at 0.01 in. lifter lift. The important point to remember is that the technician must be sure to use equivalent specification methods when comparing or selecting camshafts.
112° OVERLAP
NOTE: Fractions of a degree are commonly expressed in units called minutes (´). Sixty (60) minutes equal one degree (1°). For example, 45’ 3/4 degree, 30’ 1/2 degree, and 15’ 1/4 degree. 3. SAE camshaft specifications. SAE’s recommended practice is to measure all valve events at 0.006 in. (0.15 mm) valve lift. This method differs from the usual method used by vehicle or camshaft manufacturers. Whenever comparing valve timing events, be certain that the exact same methods are used on all camshafts being compared.
VALVE OVERLAP Another camshaft specification is the number of degrees of overlap. Valve (camshaft) overlap is the number of degrees of crankshaft rotation during which both intake and exhaust valves are open. In other words, overlap occurs at the beginning of the intake stroke and at the end of the exhaust stoke. All camshafts provide for some overlap to improve engine performance and efficiency, especially at higher engine speeds.
A lower amount of overlap results in smoother idle and low-engine speed operation, but it also means that a lower amount of power is available at higher engine speeds.
A greater valve overlap causes rougher engine idle, with decreased power at low speeds, but it also means that high-speed power is improved. Example 1: A camshaft with 50 degrees (or less) of overlap may be used in an engine in which low-speed torque and smooth idle qualities are desired. Engines used with overdrive automatic transmissions benefit from the low-speed torque and fuel economy benefits of a small-overlap cam.
Example 2: A camshaft with 100 degrees of overlap is more suitable for use with a manual transmission, with which high-RPM power is desired. An engine equipped with a camshaft with over 100 degrees of overlap tends to idle roughly and exhibit poorer low-engine speed response and lowered fuel economy. SEE FIGURE 32–33.
CALCULATING VALVE OVERLAP
An engine features a camshaft where the intake valve starts to open at 19 degrees before top dead center (BTDC) and the exhaust valve is open until 22 degrees after top dead center (ATDC). To determine overlap, total the number of degrees for which the intake valve is open BTDC (19 degrees) and the number of degrees for which the exhaust valve is open ATDC (22 degrees): Valve overlap 19 22 41 degrees
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INTAKE LOBE
EXHAUST LOBE
FIGURE 32–34 As the lobe center angle decreases, the overlap increases, with no other changes in the lobe profile lift and duration.
LOBE CENTERS
Another camshaft specification that creates some confusion is the angle of the centerlines of the intake and exhaust lobes. This separation between the centerlines of the intake and exhaust lobes is called:
Lobe center
Lobe separation
Lobe displacement angle (LDA)
Lobe spread
The lob center’s measurement is measured in degrees. SEE FIGURE 32–34. Two camshafts with identical lift and duration can vary greatly in operation because of variation in the angle between the lobe centerlines. 1. The smaller the angle between the lobe centerlines, the greater the amount of overlap. For example, 108 degrees is a narrower lobe center angle. 2. The larger the angle between the lobe centerlines, the less the amount of overlap. For example, 114 degrees is a wider lobe center angle. NOTE: Some engines that are equipped with dual overhead camshafts and four valves per cylinder use a different camshaft profile for each of the intake and exhaust valves. For example, one intake valve for each cylinder could have a cam profile designed for maximum low-speed torque. The other intake valve for each cylinder could be designed for higher engine speed power. This results in an engine that is able to produce a high torque over a broad engine speed range. To find the degree of separation between intake and exhaust lobes of a cam, use the following formula: (Intake duration ⴙ Exhaust duration)
ⴚ
Overlap
4 2 Number of degrees of separation
SEE FIGURE 32–35.
INTAKE OPENS EXHAUST CLOSES
15˚ BTDC
15˚ ATDC
ABDC
BBDC
INTAKE CLOSES
EXHAUST OPENS 59˚
59˚
FIGURE 32–35 Typical cam timing diagram.
LOBE SEPARATION ANGLE (LSA)
NARROWER
WIDER
Valve overlap
Greater
Less
Intake valve opening
Sooner
Later
Intake valve closing
Sooner
Later
Exhaust valve opening
Later
Sooner
Exhaust valve closing
Later
Sooner
Idle quality
Worst
Better
dead center (TDC) or bottom dead center (BDC) when the valves open and close.
Intake valve. The intake valves should open slightly before the piston reaches TDC and starts down on the intake stroke. This ensures that the valve is fully open when the piston travels downward on the intake stroke. The flow through a partially open valve (especially a valve ground at 45 degrees instead of 30 degrees) is greatly reduced as compared with that when the valve is in its fully open position. The intake valve closes after the piston reaches BDC because the air-fuel mixture has inertia, or the tendency of matter to remain in motion. Even after the piston stops traveling downward on the intake stroke and starts upward on the compression stroke, the inertia of the air-fuel mixture can still be used to draw in additional charge. Typical intake valve specifications are to open at 19 degrees before top dead center (BTDC) and close at 46 degrees after bottom dead center (ABDC).
Exhaust valve. The exhaust valve opens while the piston is traveling down on the power stroke, before the piston starts up on the exhaust stroke. Opening the exhaust valve before the piston starts up on the exhaust stroke ensures that the combustion pressure is released and the exhaust valve is mostly open when the piston starts up. The exhaust valve does not close until after the piston has traveled past TDC and is starting down on the intake stroke. Because of inertia of the exhaust, some of the burned gases continue to flow out the exhaust valve after the piston is past TDC. This can leave a partial vacuum in the combustion chamber to start pulling in the fresh charge. This partial vacuum is called scavenging and helps bring in a fresh air-fuel charge into the cylinders. Typical exhaust valve specifications are to open at 49 degrees before bottom dead center (BBDC) and close at 22 degrees after top dead center (ATDC).
CHART 32–1 Changing the lobe separation angle has a major effect on engine operation. The lobe separation angle can be determined by transferring the intake and exhaust duration and overlap into the formula, as follows: Intake duration 15 degrees 180 degrees 59 degrees 254 degrees Exhaust duration ⴝ 59 degrees ⴙ 180 degrees ⴙ 15 degrees ⴝ 254 degrees Overlap ⴝ 15 degrees ⴙ 15 degrees ⴝ 30 degrees The lobe separation angle can be calculated by taking the center of the intake lobe use: Intake valve duration plus exhaust valve duration divided by 4 minus the overlap divided by 2. (254 ⴙ 254)
ⴚ
30
ⴝ
508
ⴚ
30
ⴝ 127 ⴚ 15 4 2 4 2 ⴝ 112 degrees (lobe separation angle)
EFFECTS OF LOBE SEPARATION ON VALVE OPERATION SEE CHART 32–1 for what effect a change in lobe separation angle (LSA) has on engine operation.
CAM TIMING SPECIFICATIONS
Cam timing specifications are stated in terms of the angle of the crankshaft in relation to top
CAM TIMING CHART During the four strokes of a four-stroke cycle gasoline engine, the crankshaft revolves 720 degrees (it makes two complete revolutions [2 360 720 degrees]). Camshaft
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EXHAUST VALVE STARTS TO OPEN
INTAKE VALVE STARTS TO OPEN
INTAKE OPENS EXHAUST CLOSES 39° 47°
INTAKE VALVE OPEN PERIOD TDC
BDC
180˚ POWER
TDC
180˚ EXHAUST
BDC
ROTATION
TDC
180˚ COMPRESSION
180˚ INTAKE 39˚ 47˚
78˚
ROTATION
71° INTAKE CLOSES
71˚
78° EXHAUST OPENS
BOTTOM DEAD CENTER
OVERLAP 86˚
THIS VALVE TIMING DIAGRAM SHOWS TWO REVOLUTIONS (720°) OF THE CRANKSHAFT
EXHAUST VALVE OPEN PERIOD
FIGURE 32–37 Typical camshaft valve timing diagram with the same specifications as those shown in Figure 32–36. EXHAUST VALVE CLOSES
INTAKE VALVE CLOSES
FIGURE 32–36 Typical high-performance camshaft specifications on a straight-line graph. Intake valve duration 39 180 71 290 degrees. Exhaust valve duration 7 180 47 234 degrees. Because intake and exhaust valve specifications are different, the camshaft grind is called asymmetrical.
specifications are given in crankshaft degrees. In the example in FIGURE 32–36, the intake valve starts to open at 39 degrees BTDC, remains open through the entire 180 degrees of the intake stroke, and does not close until 71 degrees ATDC. Therefore, the duration of the intake valve is 39 degrees 180 degrees 71 degrees, or 290 degrees. The exhaust valve of the example camshaft opens at 78 degrees BBDC and closes at 47 degrees ATDC. When the exhaust valve specifications are added to the intake valve specifications in the diagram, the overlap period is easily observed. The overlap in the example is 39 degrees 47 degrees, or 86 degrees. The duration of the exhaust valve opening is 78 degrees 180 degrees 47 degrees, or 305 degrees. Because the specifications of this camshaft indicate close to and over 300 degrees of duration, this camshaft should only be used where power is more important than fuel economy. The usual method of drawing a camshaft timing diagram is in a circle illustrating two revolutions (720 degrees) of the crankshaft. SEE FIGURE 32–37 for an example of a typical camshaft timing diagram for a camshaft with the same specifications as the one illustrated in Figure 32–36.
FLAT TAPPET
ROLLER TAPPET
FIGURE 32–38 Older engines used flat-bottom lifters, whereas all engines since the 1990s use roller lifters.
RETAINER PLATE
LIFTERS OR TAPPETS PURPOSE AND FUNCTION
Valve lifters or tappets follow the contour or shape of the camshaft lobe. This arrangement changes the rotary cam motion to a reciprocating motion in the valve train. Older-style lifters have a relatively flat surface that slides on the cam. Most lifters, however, are designed with a roller to follow the cam contour. Roller lifters are used primarily in production engines to reduce valve train friction (by up to 8%). This friction reduction can increase fuel economy and help to offset the greater manufacturing cost. SEE FIGURE 32–38. All roller lifters must use a retainer or a guide plate to prevent lifter rotation. The retainer ensures that the roller is kept in line with the cam. SEE FIGURE 32–39.
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ROLLER LIFTERS
FIGURE 32–39 All roller lifters must use some method to keep the lifter straight and not rotating.
LIFTER BODY
LOCK RING RETAINING RING
PUSHROD CUP
PUSHROD SEAT PLUNGER OIL ENTERS LIFTER BODY HERE
OIL METERING VALVE
FIGURE 32–40 A cutaway of a flat-bottom solid lifter. Because this type of lifter contains a retaining ring and oil holes, it is sometimes confused with a hydraulic lifter that also contains additional parts. The holes in this lifter are designed to supply oil to the rocker arms through a hollow pushrod.
CHECK BALL
CHECK VALVE
VALVE LASH
Valve train clearance is also called valve lash, which is needed to help compensate for thermal expansion and wear. Valve train clearance must not be excessive, or it will cause noise or result in premature failure. Two methods are commonly used to make the necessary valve clearance adjustments.
One involves a solid valve lifter, which can be adjusted mechanically at the rocker arm or by changing shims on certain overhead camshaft engines.
The other involves a lifter with an automatic hydraulic adjustment built into the lifter body, called a hydraulic valve lifter.
BODY
ROLLER
FIGURE 32–41 An exploded view of a hydraulic roller lifter.
SOLID LIFTERS
Overhead valve engines with mechanical lifters have an adjustment screw at the pushrod end of the rocker arm or an adjustment nut at the ball pivot. Adjustable pushrods are available for specific applications. Valve trains using solid lifters must run with some clearance to ensure positive valve closure, regardless of the engine temperature. This clearance is matched by a gradual rise in the cam contour, called a ramp. (Hydraulic lifter camshafts do not have this ramp.) The ramp will take up the clearance before the valve begins to open. The camshaft lobe also has a closing ramp to ensure quiet operation. A lifter is solid in the sense that it transfers motion directly from the cam to the pushrod or valve. Its physical construction is that of a lightweight cylinder, either hollow or with a small-diameter center section and full-diameter ends. In some types that transfer oil through the pushrod, the external appearance is the same as for hydraulic lifters. SEE FIGURE 32–40.
HYDRAULIC LIFTERS A hydraulic lifter consists primarily of a hollow cylinder body enclosing a closely fit hollow plunger, a check valve, and a pushrod cup. Lifters that feed oil up through the pushrod have a metering disc or restrictor valve located under the pushrod cup. Engine oil under pressure is fed through an engine passage to the exterior lifter body. An undercut portion allows the oil under pressure to surround the lifter body. Oil under pressure goes through holes in the undercut section into the center of the plunger. From there, it goes down through the check valve to a clearance space between the bottom of the plunger and the interior bottom of the lifter body. It fills this space with oil at engine pressure. Slight leakage allowance is designed into the lifter so that the air can bleed out and the lifter can leak down if it should become overfilled.
The pushrod fits into a cup in the top, open end of the lifter plunger. Holes in the pushrod cup, pushrod end, and hollow pushrod allow oil to transfer from the lifter piston center, past a metering disc or restrictor valve, and up through the pushrod to the rocker arm. Oil leaving the rocker arm lubricates the rocker arm assembly. As the cam starts to push the lifter against the valve train, the oil below the lifter plunger is squeezed and tries to return to the lifter plunger center. A lifter check valve, either ball or disc type, traps the oil below the lifter plunger. This hydraulically locks the operating length of the lifter. The hydraulic lifter then opens the engine valve as would a solid lifter. When the lifter returns to the base circle of the cam, engine oil pressure again works to replace any oil that may have leaked out of the lifter. SEE FIGURE 32–41. The job of the hydraulic lifter is to take up all clearance in the valve train. Occasionally, engines are run at excessive speeds. This tends to throw the valve open, causing valve float. During valve float, clearance exists in the valve train. The hydraulic lifter will take up this clearance as it is designed to do. When this occurs, it will keep the valve from closing on the seat, a process called pump-up. Pump-up will not occur when the engine is operated in the speed range for which it is designed.
VALVE TRAIN LUBRICATION The lifters in an overhead valve (OHV) engine are lubricated through oil passages drilled through the block. The engine oil then flows through the lifter, and up through the hollow pushrod where the oil flows to lubricate and cool the rocker arm, valve, and valve spring.
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ROCKER ARM SHAFTS
PUSHROD PUNCHED THROUGH ROCKER ARM SPRING ROCKER ARM
FIGURE 32–42 The cause of a misfire diagnostic trouble code was discovered to be a pushrod that had worn through the rocker arm on a General Motors 3.1 liter V-6 engine.
NOTE: The Chrysler 5.7 liter Hemi engine is opposite because the oil is first sent to the rocker arm through passages in the block and head and then down through the hollow pushrod to the lifters. In all other engine designs, the oil flows through the lifter and up to the rocker arm through the hollow pushrod.
FIGURE 32–43 Shaft-mounted rocker arms are held in position by an assortment of springs, spacers, and washers, which should be removed so that the entire shaft can be inspected for wear. the oil level. If low, the oil may have been aerated (air mixed with the oil), which would prevent proper operation of the hydraulic lifter. Aeration can be caused by:
Low oil pressure, which can also cause all valves to be noisy
The oil level being too high, which can also cause noisy valve lifters (The crankshaft counterweights create foam as they rotate through the oil. This foam can travel through the oiling systems to the lifters. The foam in the lifters prevents normal operation and allows the valves to make noise.)
CAMSHAFT LUBRICATION
The camshaft in overhead valve (OHV) engines is lubricated by splash oil thrown up by the movement of the crankshaft counterweights and connecting rods. At low engine speed there is less splash lubrication than occurs at higher engine speeds. This is the major reason why an engine equipped with flat-bottom lifters should be operated at a fast idle of about 2,500 RPM during the first 10 minutes of engine operation. The high idle speed helps ensure that there is enough splash oil to properly lubricate and break in a new camshaft and lifters.
VALVE TRAIN PROBLEM DIAGNOSIS SYMPTOMS
A camshaft with a partially worn lobe is often difficult to diagnose. Sometimes a valve “tick, tick, tick” noise is heard if the cam lobe is worn. The ticking noise can be intermittent, which makes it harder to determine the cause. If the engine has an overhead camshaft (OHC), it is usually relatively easy to remove the cam cover and make a visual inspection of all cam lobes and the rest of the valve train. In an overhead valve (OHV) engine, the camshaft is in the block, where easy visual inspection is not possible. However, it always pays to perform a visual inspection. SEE FIGURE 32–42.
VALVE NOISE DIAGNOSIS
Valve lifters are often noisy, especially at engine start-up. When the engine is off, some valves are open. The valve spring pressure forces the inner plunger to leak down (oil is forced out of the lifter). Therefore, many vehicle manufacturers consider valve ticking at one-half engine speed after start-up to be normal, especially if the engine is quiet after 10 to 30 seconds. Be sure that the engine is equipped with the correct oil filter, and that the filter has an internal check valve. If in doubt, use an original equipment oil filter. If all of the valves are noisy, check
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If the valves are abnormally noisy, remove the valve cover and use a stethoscope to listen or apply pressure to the rocker arms to determine which valves or valve train parts may be causing the noise. Check for all of the following items.
Valve lash too loose
Worn camshaft lobe
Dirty, stuck, or worn lifters
Worn rocker arm (if the vehicle is so equipped)
Worn rocker arm shaft ( SEE FIGURE 32–43.)
Worn or bent pushrods (if the vehicle is so equipped)
Broken or weak valve springs
Sticking or warped valves
Any of the above can cause the engine to idle roughly, misfire, or even backfire during acceleration.
CAMSHAFT REMOVAL CAM-IN-BLOCK ENGINES If the engine is of an overhead valve (OHV) design, the camshaft is usually located in the block above the crankshaft. The timing chain and gears (if the vehicle is so equipped) should be removed after the timing chain (gear) cover is removed. Loosen the rocker arms (or rocker arm shaft) and remove the pushrods. Then remove the valve lifters before removing the camshaft from the block. NOTE: Be sure to keep the pushrods and rocker arms together if they are to be reused.
TECH TIP The Rotating Pushrod Test To quickly and easily test whether the camshaft is okay, observe if the pushrods are rotating when the engine is running. This test will work on any overhead valve pushrod engine that uses flat-bottom lifters. Due to the slight angle on the cam lobe and lifter offset, the lifter (and pushrod) should rotate whenever the engine is running. To check, simply remove the rocker arm cover and observe the pushrods when the engine is running. If one or more pushrods are not rotating, this camshaft and/or the lifter for that particular valve is worn and needs to be replaced.
REAL WORLD FIX The Noisy Camshaft The owner of an overhead cam 4-cylinder engine complained of a noisy engine. After taking the vehicle to several technicians and getting high estimates to replace the camshaft and followers, the owner tried to find a less expensive solution. Finally, another technician replaced the serpentine drive belt on the front of the engine and “cured” the “camshaft” noise for a fraction of the previous estimates. Remember, accessory drive belts can often make noises similar to valve or bad bearing types of noises. Many engines have been disassembled and/or overhauled because of a noise that was later determined to be from one of the following: • Loose or defective accessory drive belt(s) • Loose torque converter-to-flex plate (drive plate) bolts (nuts) • Defective mechanical fuel pump (if equipped)
MEASURING CAMSHAFTS TOTAL INDICATOR RUNOUT All camshafts should be checked for straightness by placing them on V-blocks and measuring the cam bearings for runout by using a dial indicator. The maximum total indicator runout (TIR) (also called total indicated runout) should be less than 0.002 in. (0.05 mm). CAM LOBE HEIGHT
Sometimes the camshaft lobe height needs to be measured to verify the exact camshaft that is installed in the engine. This can be done by attaching a dial indicator and then slowly rotating the engine while observing the indicator and comparing the measurement to factory specifications. SEE FIGURE 32–44.
SELECTING A CAMSHAFT DETERMINING ENGINE USAGE
For stock rebuilds, use a replacement camshaft with the same specifications as the engine had from the factory for like-new performance. However, if more power
FIGURE 32–44 A dial indicator being used to measure cam lobe height.
TECH TIP Hot Lifter in 10 Minutes? A technician working at a shop discovered a noisy (defective) valve lifter on an older Chevrolet small block V-8. Another technician questioned how long it would take to replace the lifter and was told, “Less than an hour”! (The factory flat rate was much longer than one hour.) Ten minutes later the repair technician handed the questioning technician a hot lifter that had been removed from the engine. The lifter was removed using the following steps. 1. The valve cover was removed. 2. The rocker arm and pushrod for the affected valve were removed. 3. The distributor was removed. 4. A strong magnet was fed through the distributor opening into the valley area of the engine. (If the valve lifter is not mushroomed or does not have varnish deposits, the defective lifter can be lifted up and out of the engine; remember, the technician was working on a new vehicle.) 5. A replacement lifter was attached to the magnet and fed down the distributor hole and over the lifter bore. 6. The pushrod was used to help guide the lifter into the lifter bore. After the lifter preload was adjusted and the valve cover was replaced, the vehicle was returned to the customer in less than one hour.
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COMMON USAGE
SEAT DURATION (IN DEGREES)
LIFT (IN INCHES) 0.4
DURATION @ 0.05 IN. (IN DEGREES)
CHARACTERISTICS Smooth idle; power idle to 4500 RPM
Street
246 to 254
192 to 199
Street
262
0.432
207
Broad power range, smooth idle; power idle to 4800 RPM
Street
266
0.441
211
Good idle for 350 cu. in. engines; power idle to 5200 RPM
Street/drag strip
272
0.454
217
Low idle; power idle to 5500 RPM
Street/race track
290
0.5
239
Shaky idle; power idle to 5500 to 6500 RPM
CHART 32–2 A comparison showing the effects of valve timing and lift on engine performance.
DRIVING CONDITION
CHANGE IN CAMSHAFT POSITION
OBJECTIVE
RESULT
Idle
No change
Minimize valve overlap
Stabilize idle speed
Light engine load
Retard valve timing
Decrease valve overlap
Stable engine output
Medium engine load
Advance valve timing
Increase valve overlap
Better fuel economy with lower emissions
Low to medium RPM with heavy load
Advance valve timing
Advance intake valve closing
Improve low to midrange torque
High RPM with heavy load
Retard valve timing
Retard intake valve closing
Improve engine output
CHART 32–3 The purpose for varying the cam timing includes providing for more engine torque and power over a wide engine speed and load range.
is desired, then many engine builders will want to select a different camshaft than the stock version. A common mistake of beginning engine builders is to install a camshaft with too much duration for the size of the engine. This extended duration of valve opening results in a rough idle and low manifold vacuum, which causes lack of low-speed power. For example, a hydraulic cam with duration of greater than 225 degrees at 0.05 in. lift for a 350 cu. in. engine will usually not be suitable for street driving. Seat duration is the number of degrees of crankshaft rotation that the valve is off the seat. SEE CHART 32–2. Check with the camshaft manufacturer for their recommendation for the best camshaft to use. Be prepared to furnish them with the following information.
1. Exhaust camshaft variable action only on overhead camshaft engines, such as on many inline 4- and 6-cylinder engines 2. Intake and exhaust camshaft variable action on both camshafts used in many engines 3. Changing the relationship of the camshaft to the crankshaft, in overhead valve cam-in-block engines Variable-cam timing allows the valves to be operated at different points in the combustion cycle, to improve performance. SEE CHART 32–3. Variable camshaft timing is used on engines from the following vehicle manufacturers.
General Motors 4-, 5-, 6-, and 8-cylinder engines
Engine make and size
BMW
Weight of the vehicle
Chrysler
Type of transmission
Ford
Final drive gear ratio
Nissan/Infinity
Intended use of the vehicle
Toyota/Lexus
VARIABLE VALVE TIMING PURPOSE AND FUNCTION
Conventional camshafts are permanently synchronized to the crankshaft so that they operate the valves at a specific point in each combustion cycle. In an engine, the intake valve opens slightly before the piston reaches the top of the cylinder and closes about 60 degrees after the piston reaches the bottom of the stroke on every cycle, regardless of the engine speed or load. On newer engines, the camshaft can have the capability of a variable valve-timing feature that changes the camshaft specifications during different operating modes. For example, many vehicle manufacturers use three basic types of variable valve timing.
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On a system that controls the intake camshaft only, the camshaft timing is advanced at low engine speed, closing the intake valves earlier to improve low RPM torque. At high engine speeds, the camshaft is retarded by using engine oil pressure against a helical gear to rotate the camshaft. When the camshaft is retarded, the intake valve closing is delayed, improving cylinder filling at higher engine speeds. Variable cam timing can be used to control exhaust cam timing only. Engines that use this system, such as the 4.2 liter GM inline 6-cylinder engines, can eliminate the exhaust gas recirculation (EGR) valve because the computer can close the exhaust valve sooner than normal, trapping some exhaust gases in the combustion chamber and therefore eliminating the need for an EGR valve. Some engines use variable camshaft timing on both intake and exhaust cylinder cams.
OPERATION The camshaft position actuator oil control valve (OCV) directs oil from the oil feed in the head to the appropriate
SPROCKET
A
PADDLE CAVITY
A
CAMSHAFT
PADDLE
SECTION A-A SPROCKET
FIGURE 32–45 Camshaft rotation during advance and retard.
MAGNETICALLY ACTIVATED OIL CONTROL VALVE
ELECTROMAGNET
CAMSHAFT PHASER (VANE TYPE)
RETURN SPRING
DRIVE SPROCKET
FRONT ENGINE COVER
FIGURE 32–46 The camshaft is rotated in relation to the crankshaft by the PCM to provide changes in valve timing.
camshaft position actuator oil passages. There is one OCV for each camshaft position actuator. The OCV is sealed and mounted to the front cover. The ported end of the OCV is inserted into the cylinder head with a sliding fit. A filter screen protects each OCV oil port from any contamination in the oil supply. The camshaft position actuator is mounted to the front end of the camshaft, and the timing notch in the nose of the camshaft aligns with the dowel pin in the camshaft position actuator to ensure proper cam timing and camshaft position actuator oil hole alignment. SEE FIGURE 32–45.
OHV VARIABLE TIMING
The variable valve timing system uses an electronically controlled, hydraulic gear-driven cam phaser that can alter the relationship of the camshaft from 15 degrees retard to 25 degrees advance (40 degrees overall) relative to the crankshaft. By using variable valve timing (VVT), engineers were able to eliminate the EGR valve. The VVT also works in conjunction with an active intake manifold that gives the engine a broader torque curve. A valve in the intake manifold creates a longer path for intake air at low speeds, improving combustion efficiency and torque output. At higher speed, the valve opens and creates a shorter air path for maximum power production. SEE FIGURE 32–46.
CAMSHAFT PHASING CHANGED
IMPROVES
Exhaust cam phasing
Reduces exhaust emissions
Exhaust cam phasing
Increases fuel economy (reduced pumping losses)
Intake cam phasing
Increases low-speed torque
Intake cam phasing
Increases high-speed power
CHART 32–4 Changing the exhaust cam timing mainly helps reduce exhaust emissions, whereas changing the intake cam timing mainly helps the engine produce increased power and torque.
Varying the exhaust and/or the intake camshaft position allows for reduced exhaust emissions and improved performance. SEE CHART 32–4. By varying the exhaust cam phasing, vehicle manufacturers are able to meet newer NOx reduction standards and eliminate the exhaust gas recirculation (EGR) valve. Also by using exhaust cam phasing, the powertrain control module (PCM) can close the exhaust valves sooner than usual, thereby trapping some exhaust gases in
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FLOATING PISTON
STRAIGHT-CUT SPLINES
RELECTOR
HELICAL SPLINES
EXHAUST CAMSHAFT
DRIVE SPROCKET (FROM CRANKSHAFT)
OIL APPLIED
OIL APPLIED
RETARD POSITION
ADVANCE POSITION
FIGURE 32–47 Spline cam phaser assembly.
the combustion chamber. Manufacturers use one or two actuators that allow the camshaft piston to change by up to 50 degrees in relation to the crankshaft position. The two types of cam phasing devices commonly used are:
Spline phaser. Used on overhead camshaft (OHC) engines
Vane phaser. Used on overhead camshaft (OHC) and overhead valve (OHV) cam-in-block engines
SPLINE PHASER SYSTEM The spline phaser system is also called the valve cam phaser (VCP) and consists of the following components.
Engine control module (ECM)
Four-way pulse-width-modulated (PWM) control valve
Cam phaser assembly
Camshaft position (CMP) sensor
SEE FIGURE 32–47.
SPLINE PHASER SYSTEM OPERATION
On most engines, the pulse-width-modulated (PWM) control valve is located on the front of the cylinder head. Oil pressure is regulated by the control valve and then directed to the ports in the cylinder head leading to the camshaft and cam phaser position. The cam phaser is located on the exhaust cams and is part of the exhaust cam sprocket. When the PCM commands an increase in oil pressure, the piston is moved inside the cam phaser and rides along the helical splines, which compresses the coil spring. This movement causes the cam phaser gear and the camshaft to move in an opposite direction, thereby retarding the cam timing. SEE FIGURE 32–48. NOTE: A unique cam-within-a-cam is used on 2008 and newer Dodge Viper V-10 OHV engines. This design allows the exhaust lobes to be moved by up to 36 degrees to improve idle quality and reduction of exhaust emissions.
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TECH TIP Check the Screen on the Control Valve If There Are Problems If a NOx emission failure at a state inspection occurs or a diagnostic trouble code is set related to the cam timing, remove the control valve and check for a clogged oil screen. A lack of regular oil changes can cause the screen to become clogged, thereby preventing proper operation. A rough idle is a common complaint because the spring may not be able to return the camshaft to the idle position after a long highway trip. SEE FIGURE 32–49.
VANE PHASER SYSTEM ON AN OVERHEAD CAMSHAFT ENGINE The vane phaser system used on overhead camshaft (OHC) engines uses a camshaft piston (CMP) sensor on each camshaft. Each camshaft has its own actuator and its own oil control valve (OCV). Instead of using a piston along a helical spline, the vane phaser uses a rotor with four vanes, which is connected to the end of the camshaft. The rotor is located inside the stator, which is bolted to the cam sprocket. The stator and rotor are not connected. Oil pressure is controlled on both sides of the vanes of the rotor, which creates a hydraulic link between the two parts. The oil control valve varies the balance of pressure on either side of the vanes and thereby controls the position of the camshaft. A return spring is used under the reluctor of the phaser to help return it to the home or zero degrees position. SEE FIGURE 32–50.
MAGNETICALLY CONTROLLED VANE PHASER
On this type, the PCM controls a magnetically controlled vane phaser by using a 12 volt pulse-width-modulated (PWM) signal to an
MAP SENSOR
CRANKSHAFT POSITION SENSOR (CKP)
RPM
POWERTRAIN CONTROL MODULE (PCM)
CAMSHAFT POSITION SENSOR (CMP)
PWM CONTROL VALVE
SPRING PISTON VENT HELICAL SPLINE (PART OF CAM)
VENT
ENGINE OIL PRESSURE
CAMSHAFT
RELUCTOR WHEEL TOOTH
SPROCKET
FIGURE 32–48 A spline phaser. ENGINE OIL PRESSURE OIL CONTROL VALVE (OCV) SCREENS
SPROCKET
PADDLE CAVITY RETARD ADVANCE
CAMSHAFT PADDLE
FIGURE 32–49 The screen(s) protect the solenoid valve from dirt and debris that can cause the valve to stick. This fault can set a P0017 diagnostic trouble code (crankshaft position/camshaft position correlation error). electromagnet, which operates the oil control valve (OCV). A magnetically controlled vane phaser is used on many double overhead camshaft engines on both the intake and exhaust camshafts. The OCV directs pressurized engine oil to either advance or retard chambers of the camshaft actuator to change the camshaft position in relation to the crankshaft position. SEE FIGURE 32–51.
SPROCKET
FIGURE 32–50 A vane phaser is used to move the camshaft, using changes in oil pressure from the oil control valve. The following occurs when the pulse width is changed.
0% pulse width. The oil is directed to the advance chamber of the exhaust camshaft actuator and the retard chamber of the intake camshaft activator.
50% pulse width. The computer is holding the camshaft steady in the desired position.
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100% pulse width. The oil is directed to the retard chamber of the exhaust camshaft actuator and the advance chamber of the intake camshaft actuator.
The cam phasing is continuously variable with a range from 40 degrees for the intake camshaft and 50 degrees for the exhaust camshaft. The ECM uses the following sensors to determine the best position of the camshaft for maximum power and lowest possible exhaust emissions.
Engine speed (RPM)
MAP sensor
Crankshaft position (CKP)
Camshaft position (CMP)
Barometric pressure (BARO)
CAM-IN-BLOCK ENGINE CAM PHASER
Overhead valve engines that use a cam-in-block design use a magnetically controlled cam phaser to vary the camshaft in relation to the crankshaft. This type of phaser is not capable of changing the duration of valve opening or valve lift. Inside the camshaft actuator is a rotor with vanes that are attached to the camshaft. Oil pressure is supplied to the vanes, which causes the camshaft to rotate in relation to the crankshaft. The camshaft actuator solenoid valve directs the flow of oil to either the advance or retard side vanes of the actuator. SEE FIGURE 32–52. The ECM sends a pulse-width-modulated (PWM) signal to the camshaft actuator magnet. The movement of the pintle is used to direct oil flow to the actuator. The higher the duty cycle is, the greater the movement in the valve position and change in camshaft timing. DRIVE CHAIN
NOTE: When oil pressure drops to zero when the engine stops, a spring-loaded locking pin is used to keep the camshaft locked to prevent noise at engine start. When the engine starts, oil pressure releases the locking pin.
VARIABLE LIFT AND CYLINDER DEACTIVATION SYSTEMS VARIABLE VALVE LIFT SYSTEMS Variable camshafts include the system used by Honda/Acura, called variable valve timing and lift electronic control (VTEC). This system uses two different camshafts for low and high RPM. When the engine is operating at idle and speeds below about 4000 RPM, the valves are opened by camshafts that are optimized by maximum torque and fuel economy. When engine speed reaches a predetermined speed, depending on the exact make and model, the computer turns on a solenoid, which opens a spool valve. When the spool valve opens, engine oil pressure pushes against pins that lock the three intake rocker arms together. With the rocker arms lashed, the valves must follow the profile of the high RPM cam lobe in the center. This process of switching from the low-speed camshaft profile to the high-speed profile takes about 100 milliseconds (0.1 sec). SEE FIGURES 32–53 AND 32–54.
VANE
CONTROL VALVE VARIABLE RANGE
ELECTROMAGNET RETURN SPRING
DRIVE SPROCKET
FIGURE 32–53 A plastic mockup of a Honda VTEC system that uses two different camshaft profiles—one for low-speed engine operation and the other for high speed.
FIGURE 32–51 A magnetically controlled vane phaser.
SPOOL VALVE SPOOL SPRING
FILTER
OIL FEED HOLES (4)
SPRING CHECK BALL
CAMSHAFT POSITION (CMP) ACTUATOR SOLENOID VALVE
FIGURE 32–52 A camshaft position actuator used in a cam-in-block engine.
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CAMSHAFT
OUTER CAM LOBE CENTER CAM LOBE
OUTER FOLLOWER CENTER INTAKE FOLLOWER CAMSHAFT OUTER FOLLOWER
LIFTER OIL MANIFOLD ASSEMBLY EXHAUST CAMSHAFT LOCKING PIN ASSEMBLY
OUTER CAM LOBE
TWO-STAGE LIFTER
FIGURE 32–54 Engine oil pressure is used to switch cam lobes on a VTEC system.
UNAPPLIED PRESSURE SPRING PUSHES THE LOCKING PIN OUTWARD
LIFTER ENABLED
HIGH-CAPACITY GEROTOR PUMP
FIGURE 32–56 Active fuel management includes many different components and changes to the oiling system, which makes routine oil changes even more important on engines equipped with this system.
CYLINDER DEACTIVATION SYSTEMS Some engines are designed to operate on four of eight cylinders, or three of six cylinders, during low load conditions to improve fuel economy. The powertrain control module (PCM) monitors engine speed, coolant temperature, throttle position, and load, and determines when to deactivate cylinders. The key to this process is the use of two-stage hydraulic valve lifters. In normal operation, the inner and outer lifter sleeves are held together by a pin and operate as an assembly. When the computer determines that the cylinder can be deactivated, oil pressure is delivered to a passage, which depresses the pin and allows the outer portion of the lifter to follow the contour of the cam while the inner portion remains stationary, keeping the valve closed. The electronic operation is achieved through the use of the lifter oil manifold containing solenoids to control the oil flow, which is used to activate or deactivate the cylinders. General Motors once called this system “displacement on demand (DOD),” but now calls it “active fuel management.” Chrysler calls this a “multiple displacement system (MDS).” SEE FIGURES 32–55 AND 32–56.
A PR PP ES LIE SU D R E
ENGINE OIL PRESSURE PUSHES THE LOCKING PIN INWARD
LIFTER DISABLED
FIGURE 32–55 Oil pressure applied to the locking pin causes the inside of the lifter to freely move inside the outer shell of the lifter, thereby keeping the valve closed.
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REVIEW QUESTIONS 1. Explain why the lift and duration and lobe displacement angle (LDA) dimension of the camshaft determine the power characteristics of the engine.
3. Describe the operation of a hydraulic lifter. 4. Describe how variable valve timing works.
2. List the terms that mean the same as lobe displacement angle (LDA).
CHAPTER QUIZ 1. The camshaft makes ______________ for every revolution of the crankshaft. a. One-quarter revolution c. One revolution b. One-half revolution d. Two revolutions 2. Flat-bottom valve lifters rotate during operation because of the ______________ of the camshaft. a. Taper of the lobe c. Chain tensioner b. Thrust plate d. Bearings 3. If lift and duration remain constant and the lobe center angle decreases, then ______________. a. The valve overlap decreases b. The effective lift increases c. The effective duration increases d. The valve overlap increases 4. Which timing chain type is also called a “silent chain”? a. Roller c. Flat link b. Morse d. Both b and c 5. Two technicians are discussing variable valve timing. Technician A says that changing the exhaust valve timing helps reduce exhaust emissions. Technician B says that changing the intake valve timing helps increase low-speed torque. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
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6. Many technicians always use new pushrods because ___________. a. They are less expensive to buy than clean b. All of the dirt cannot be cleaned out from the hollow center c. They wear at both ends d. They shrink in length if removed from an engine 7. A DOHC V-6 has how many camshafts? a. 4 c. 2 b. 3 d. 1 8. The intake valve opens at 39 degrees BTDC and closes at 71 degrees ABDC. The exhaust valve opens at 78 degrees BBDC and closes at 47 degrees ATDC. Which answer is correct? a. Intake valve duration is 110 degrees. b. Exhaust valve duration is 125 degrees. c. Overlap is 86 degrees. d. Both a and b 9. Hydraulic valve lifters can make a ticking noise when the engine is running if ______________. a. The valve lash is too close b. The valve lash is too loose c. The lobe centerline is over 110 degrees d. Both a and c 10. Hydraulic lifters or hydraulic lash adjusters (HLA) may not bleed down properly and cause an engine miss if ______________. a. The engine oil is 1 quart low b. The wrong API-rated engine oil is used c. The wrong SAE-rated engine oil is used d. Both a and b
PISTONS, RINGS, AND CONNECTING RODS
OBJECTIVES: After studying Chapter 33, the reader should be able to: • Prepare for Engine Repair (A1) ASE certification test content area “C” (Engine Block Diagnosis and Repair). • Describe the purpose and function of pistons, rings, and connecting rods. • Explain how pistons and rods are constructed and what to look for during an inspection. • Discuss connecting rod reconditioning procedures. • Explain how piston rings operate and how to install them on a piston. KEY TERMS: Back clearance 343 • Balancing bosses (pads) 346 • Barrel face ring 344 • Bleed hole 346 • Blowby 343 • Cam ground 339 • Compression rings 343 • Connecting rod bearing journal 337 • Crankpin 337 • Crank throw 337 • Double knock 341 • Ductile iron 344 • Freewheeling 339 • Full floating 341 • Grooves 337 • Heat dams 339 • Hypereutectic 338 • Interference fit 342 • Lands 337 • Lock rings 342 • Major thrust surface 340 • Oil control ring 343 • Piston 337 • Piston pin 337 • Piston ring expander 350 • Piston rings 337 • Positive twist ring 344 • Reverse twist ring 344 • Ring gap 343 • Scraper ring 344 • Side clearance 343 • Skirt 337 • Slipper skirt 339 • Spit hole 346 • Struts 340 • Taper face ring 344 • Wrist pin 337
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COMPRESSION RING GROOVES
PISTON RING LAND
CROWN
OIL RING GROOVE
SKIRT
WRIST PIN BOSS
FIGURE 33–2 All pistons share the same parts in common.
CONNECTING ROD
FIGURE 33–1 The piston seals the bottom of the combustion chamber and is attached to a connecting rod.
PISTONS PURPOSE AND FUNCTION
All engine power is developed by burning fuel mixed with air in the combustion chamber. Heat from the combustion causes the burned gas to increase in pressure. The force of this pressure is converted into useful work through the piston, connecting rod, and crankshaft. Therefore, the piston serves three purposes. 1. Transfers force. The piston transfers the force of combustion to the crankshaft through the connecting rod. 2. Seals the combustion chamber. The piston and piston rings seal the compressed air during the compression stroke and the combustion gases on the power stroke. 3. Conducts heat. The piston transfers heat from the combustion chamber to the cylinder walls through the piston rings and to the engine oil through the piston.
PARTS INVOLVED The piston forms a movable bottom to the combustion chamber. SEE FIGURE 33–1. The piston is attached to the connecting rod with a piston pin, also called a wrist pin. The piston pin is allowed to have a rocking movement because of a swivel joint at the piston end of the connecting rod. The crankshaft changes the up-and-down (reciprocating) motion of the pistons into rotary motion. The connecting rod is connected to a part of the crankshaft called a crank throw, crankpin, or connecting rod bearing journal. Piston rings seal the small space between the piston and cylinder wall, keeping the pressure above the piston. When the pressure builds up in the combustion chamber, it pushes on the piston. The piston, in turn, pushes on the piston pin and upper end of the connecting rod. The lower end of the connecting rod pushes on the crank throw. This provides the force to turn the crankshaft. As the crankshaft turns, it develops inertia. Inertia is the force that
causes the crankshaft to continue rotating. This action will bring the piston back to its original position, where it will be ready for the next power stroke. While the engine is running, the combustion cycle keeps repeating as the piston reciprocates (moves up and down) and the crankshaft rotates.
PISTON OPERATION When the engine is running, the piston starts at the top of the cylinder. As it moves downward, it accelerates until it reaches a maximum velocity slightly before it is halfway down. The piston comes to a stop at the bottom of the cylinder at 180 degrees of crankshaft rotation. During the next 180 degrees of crankshaft rotation, the piston moves upward. It accelerates to reach a maximum velocity slightly above the halfway point and then comes to a stop at the top of the stroke. Thus, the piston starts, accelerates, and stops twice in each crankshaft revolution. NOTE: A typical piston in an engine operating at 4000 RPM accelerates from 0 to 60 mph (97 km/h) in about 0.004 second (4 ms) as it travels about halfway down the cylinder. This reciprocating action of the piston produces large inertia forces. Inertia is the force that causes a part that is stopped to stay stopped or a part that is in motion to stay in motion. The lighter the piston can be made, the less inertia force that is developed. Less inertia will allow higher engine operating speeds. For this reason, pistons are made to be as light as possible while still having the strength that is needed. The piston operates with its top or head exposed to the hot combustion gases, whereas the skirt contacts the relatively cool cylinder wall. This results in a temperature difference of about 275°F (147°C) between the top and bottom of the piston.
PISTON CONSTRUCTION PISTON RING GROOVES
Piston ring grooves are located between the piston head and skirt. The width of the grooves, the width of the lands between the ring grooves, and the number of rings are major factors in determining minimum piston height. The outside diameter of the lands is about 0.02 to 0.04 in. (0.5 to 1 mm) smaller than the skirt diameter. SEE FIGURE 33–2. SEE FIGURE 33–3 for an example of how to measure the diameter of a piston.
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FIGURE 33–4 A cast piston showing the sprues which were used to fill the mold with molten aluminum alloy.
375°
450°
FIGURE 33–3 A piston diameter is measured across the thrust surfaces.
425°
415°
300°
TECH TIP 250°
Piston Weight Is Important! All pistons in an engine should weigh the same to help ensure a balanced engine. Piston weight becomes a factor when changing pistons. Most aluminum pistons range in weight from 10 to 30 ounces (280 to 850 grams) (1 oz 28.35 g). A typical paper clip weighs 1 g. If the cylinder has been bored, larger replacement pistons are obviously required. If the replacement pistons weigh more, this puts additional inertia loads on the rod bearings. Therefore, to help prevent rod bearing failure on an overhauled engine, the replacement pistons should not weigh more than the original pistons.
300° FORGED
550° 350°
200°
500°
CAUTION: Some less expensive replacement cast pistons or high-performance forged pistons are much heavier than the stock pistons, even in the stock bore size. This means that the crankshaft may need heavy metal added to the counterweights of the crankshaft for the engine to be balanced. For the same reason, if one piston is being replaced, all pistons should be replaced or at least checked and corrected to ensure the same weight.
450°
350°
300°
275°
200° CAST
CAST PISTONS
Cast aluminum pistons usually are made using gravity die casting. In this process, molten aluminum alloy and about 10% silicon are poured into a mold. The silicon is used to increase the strength and help control the expansion of the piston when it gets hot. Other metals used in the aluminum alloy include copper, nickel, manganese, and magnesium. SEE FIGURE 33–4.
HYPEREUTECTIC PISTONS A standard cast aluminum piston contains about 9% to 12% silicon and is called a eutectic piston. To add strength, the silicon content is increased to about 16%, and the resulting piston is called a hypereutectic piston. Other advantages of a hypereutectic piston are its 25% weight reduction and lower expansion rate. The disadvantage of hypereutectic pistons is their higher cost, because they are more difficult to cast and machine. Hypereutectic pistons are commonly used in the aftermarket and as original equipment in many turbocharged and supercharged engines.
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FIGURE 33–5 The top of the piston temperature can be 100°F (38°C) lower on a forged piston compared to a cast piston.
FORGED PISTONS High-performance engines need pistons with added strength. Forged pistons have a dense grain structure and are very strong. Forged pistons are often used in turbocharged or supercharged engines. Because forged pistons are less porous than cast pistons, they conduct heat more quickly. Forged pistons generally run about 20% cooler than cast pistons. SEE FIGURE 33–5. PISTON HEAD DESIGNS Because the piston head forms a portion of the combustion chamber, its shape is vital to the combustion process. Many newer engines have flat-top pistons. Some of these flat-top pistons come so close to the cylinder head that recesses are cut in the piston top for valve clearance. Pistons used in high-powered engines may have raised domes or pop-ups on the
DIRECTION OF EXPANSION B
A
THRUST SURFACES
DIA. A - DIA. B = CAM PISTON SKIRT
FIGURE 33–6 Valve reliefs are used to provide valve clearance.
FIGURE 33–7 Piston cam shape. The largest diameter is across the thrust surfaces and perpendicular to the piston pin (labeled A).
piston heads. These are used to increase the compression ratio. Pistons used in other engines may be provided with a depression or a dish. The varying depths of the dish provide different compression ratios required by different engine models. NOTE: Newer engines do not use valve reliefs because this requires that the thickness of the top of the piston be increased to provide the necessary strength. The thicker the top of the piston, the farther down from the top the top piston ring sits. To reduce unburned hydrocarbon (HC) exhaust emissions, engineers attempt to place the top piston ring as close to the top of the piston as possible to prevent the unburned fuel from being trapped (and not burned) between the top of the piston and the top of the top piston ring. Recesses machined or cast into the tops of the pistons for valve clearance are commonly called:
Eyebrows
Valve reliefs
Valve pockets
The depth of the eyebrows has a major effect on the compression ratio and is necessary to provide clearance for the valves if the timing belt or chain of an overhead camshaft engine should break. Without the eyebrows, the pistons could hit the valves near TDC if the valves are not operating (closing) because of nonrotation of the camshaft. If an engine is designed not to have the pistons hitting the valves, if the timing belt or chain breaks, the engine is called freewheeling. SEE FIGURE 33–6.
SLIPPER SKIRT PISTONS A slipper skirt design piston is shorter on the two sides that are not thrust surfaces. Advantages of using a slipper skirt design include:
Lighter weight
Allows for a shorter overall engine height, because the crankshaft counterweights can be closer to the piston when they are at the bottom of the stroke Most engines today use a slipper skirt piston design.
CAM GROUND PISTONS Aluminum pistons expand when they get hot. A method of expansion control was devised using a cam ground piston skirt. With this design, the piston thrust surfaces closely fit the cylinder, and the piston pin boss diameter is fitted loosely. As the cam ground piston is heated, it expands
FIGURE 33–8 A moly graphite coating on this piston from a General Motors 3800 V-6 engine helps to prevent piston scuffing. along the piston pin so that it becomes nearly round at its normal operating temperatures. A cam ground piston skirt is illustrated in FIGURE 33–7.
PISTON FINISH The finish on piston skirts varies with the manufacturer, but all are designed to help reduce scuffing. Scuffing is a condition where the metal of the piston actually contacts the cylinder wall. When the piston stops at the top of the cylinder, welds or transfer of metal from one part to the other can take place. Scuffing can be reduced by coating the piston skirts with tin 0.0005 in. (0.0125 mm) thick or a moly graphite coating. SEE FIGURE 33–8. PISTON HEAD SIZE
The top or head of the piston is smaller in diameter than the rest of the piston. The top of the piston is exposed to the most heat and therefore tends to expand more than the rest of the piston. SEE FIGURE 33–9. Most pistons have horizontal separation slots that act as heat dams. These slots reduce heat transfer from the hot piston head to the lower skirt. This, in turn, keeps the skirt temperature lower to reduce skirt expansion. Because the slot is placed in the oil ring groove, it can be used for oil drainback and expansion control.
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TAPERED BORE
.030" TO .038" LESS THAN DIAMETER AT C B A 45°
C
C F
F
D
STRAIGHT BORE
D
A B
DIAMETERS AT (C) AND (D) CAN BE EQUAL OR DIAMETER AT (D) CAN BE .0015" GREATER THAN (C).
THE ELLIPTICAL SHAPE OF THE PISTON SKIRT SHOULD BE .010" TO .012" LESS AT DIAMETER (A) THAN ACROSS THE THRUST FACES AT DIAMETER (B). MEASUREMENT IS MADE 1/8" BELOW LOWER RING GROOVE.
FIGURE 33–11 Most piston pins are hollow to reduce weight and have a straight bore. Some pins have a tapered bore to reinforce the pin.
PISTON CENTERLINE
FIGURE 33–9 The head of the piston is smaller in diameter than the skirt of the piston to allow it to expand when the engine is running.
MAJOR THRUST SURFACE
OFFSET PISTON PIN CENTERLINE STEEL STRUT
FIGURE 33–10 Steel struts cast inside the piston help control expansion and add strength to the piston pin area.
PISTON STRUT INSERTS
A major development in expansion control occurred when the piston aluminum was cast around two stiff steel struts.
The struts add strength to the piston in the piston pin area where additional strength is needed.
The struts help control thermal expansion.
Pistons with steel strut inserts allow good piston-to-cylinder wall clearance at normal temperatures. At the same time, they allow the cold operating clearance to be as small as 0.0005 in. (one-half thousandth of an inch) (0.0127 mm). This small clearance will prevent cold piston slap and noise. A typical piston expansion control strut is visible in FIGURE 33–10.
PISTON PINS TERMINOLOGY
Piston pins are used to attach the piston to the connecting rod. Piston pins are also known as wrist pins or gudgeon pins, a British term. The piston pin transfers the force produced by
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FIGURE 33–12 Piston pin offset toward the major thrust surface.
combustion chamber pressures and piston inertia to the connecting rod. The piston pin is made from high-quality steel in the shape of a tube to make it both strong and light. Sometimes, the interior hole of the piston pin is tapered, so it is large at the ends and small in the middle of the pin. This gives the pin strength that is proportional to the location of the load placed on it. A double-taper hole such as this is more expensive to manufacture, so it is used only where its weight advantage merits the extra cost. SEE FIGURE 33–11.
PISTON PIN OFFSET Some piston pin holes are not centered in the piston. They are located toward the major thrust surface, approximately 0.062 in. (1.57 mm) from the piston centerline, as shown in FIGURE 33–12.
BTDC COMPRESSION STROKE
CROSSOVER AT THE START OF THE POWER STROKE
ATDC POWER STROKE
FIGURE 33–13 Engine rotation and rod angle during the power stroke cause the piston to press harder against one side of the cylinder, called the major thrust surface.
?
FREQUENTLY ASKED QUESTION
Which Side Is the Major Thrust Side? The thrust side is the side the rod points to when the piston is on the power stroke. Any V-block engine (V-6 or V-8) that rotates clockwise is viewed from the front of the engine. The left bank piston thrust side faces the inside (center) of the engine. The right bank piston thrust side faces the outside of the block. This rule, called the lefthand rule, states the following: • Stand at the rear of the engine and point toward the front of the engine. • Raise your thumb straight up, indicating the top of the engine. • Point your other fingers toward the right. This represents the major thrust side of the piston. Always assemble the connecting rods onto the rods so that the notch or “F” on the piston is pointing toward the front of the engine and the oil squirt hole on the connecting rod is pointing toward the major thrust side with your left hand.
Pin offset is designed to reduce piston slap and the noise that can result as the large end of the connecting rod crosses over top dead center.
Minor thrust. The minor thrust side of the piston head has a greater area than the major side. This is caused by the pin offset. As the piston moves up in the cylinder on the compression stroke, it rides against the minor thrust surface. When compression pressure becomes high enough, the greater head area on the minor side causes the piston to cock slightly in the cylinder. This keeps the top of the minor thrust surface on the cylinder. It forces the bottom of the major thrust surface to contact the cylinder wall. As the piston approaches top center, both thrust surfaces are in contact with the cylinder wall. Major thrust. When the crankshaft crosses over top center, the force on the connecting rod moves the entire piston
toward the major thrust surface. The lower portion of the major thrust surface has already been in contact with the cylinder wall. The rest of the piston skirt slips into full contact just after the crossover point, thereby controlling piston slap. This action is illustrated in FIGURE 33–13. Off-setting the piston toward the minor thrust surface would provide a better mechanical advantage. It also would cause less piston-to-cylinder friction, and increase piston noise. For these reasons, the offset is often placed toward the minor thrust surface in racing engines. Noise and durability are not as important in racing engines as maximum performance. NOTE: Not all piston pins are offset. In fact, many engines operate without the offset to help reduce friction and improve power and fuel economy.
PISTON PIN FIT The finish and size of piston pins are closely controlled. Piston pins have a smooth, mirrorlike finish. Their size is held to tens of thousandths of an inch so that exact fits can be maintained. If the piston pin is loose in the piston or in the connecting rod, it will make a sound while the engine is running. This is often described as a double knock. The noise is created when the piston stops at top dead center and occurs again as it starts to move downward, creating a doubleknock or rattling sound. If the piston pin is too tight in the piston, it will restrict piston expansion along the pin diameter and lead to piston scuffing. Normal piston pin clearances range from 0.0005 to 0.0007 in. (0.0126 to 0.018 mm).
PISTON PIN RETAINING METHODS FULL FLOATING
Full-floating piston pins are free to “float” in the connecting rod and the piston. Often, a bronze bushing is installed in the small end of the connecting rod to support the piston pin. Full-floating pins require a retaining device to keep the piston pin from moving endwise and scrape against the cylinder wall. Most
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CIRCLIP
HEAT SOURCE
WRIST PIN
PISTON
MACHINED SLOT
FIGURE 33–14 Circlips hold full-floating piston pins in place. PISTON PIN COOLANT
FIGURE 33–16 The rings conduct heat from the piston to the cylinder wall.
REAL WORLD FIX Big Problem, No Noise Sometimes the piston pin can “walk” off the center of the piston and score the cylinder wall. This scoring is often not noticed because this type of wear does not create noise. Because the piston pin is below the piston rings, little combustion pressure is lost past the rings until the groove worn by the piston pin has worn the piston rings. Troubleshooting the exact cause of the increased oil consumption is difficult because the damage done to the oil control rings by the groove usually affects only one cylinder. Often, compression tests indicate good compression because of the cylinder seals, especially at the top. More than one technician has been surprised to see the cylinder gouged by a piston pin when the cylinder head has been removed for service. In such a case, the cost of the engine repair immediately increases far beyond that of normal cylinder head service.
FIGURE 33–15 A typical interference fit piston pin. full-floating piston pins use some type of lock ring to retain the piston pin. There are two common types of lock rings.
One is an internal snap ring that fits into a groove in the piston pin bore. These internal snap rings or “circle clips” are commonly called “circlips”.
The other is a “spiral lock” ring, which is a wound flat ring with two or three layers made from hardened steel. The spiral lock is inserted into a groove cut into the piston pin bore by starting with the bottom layer and twisting the spiral ring into place until all layers are in the groove.
Full-floating piston pins are most often used in high-performance modified engines and in diesel engines. SEE FIGURE 33–14. Some engines use aluminum or plastic plugs in both ends of the piston pin. These plugs touch the cylinder wall without scoring, to hold the piston pin centered in the piston.
INTERFERENCE FIT
Another method of retaining the piston pin in the connecting rod is to make the connecting rod hole slightly smaller than the piston pin. The pin is installed by heating the rod to expand the hole or by pressing the pin into the rod. This retaining method will securely hold the pin. SEE FIGURE 33–15. This press or shrink fit is called an interference fit. Care must be taken to have the correct hole sizes, and the pin must be centered in the connecting rod. Because the interference fit method is the least expensive to use, it is found in the majority of engines.
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PISTON RINGS PURPOSE AND FUNCTION
Piston rings serve several major
functions in engines.
They form a sliding combustion chamber seal that prevents the high-pressure combustion gases from leaking past the piston.
They keep engine oil from getting into the combustion chamber.
The rings transfer some of the piston heat to the cylinder wall, where it is removed from the engine through the cooling system. SEE FIGURE 33–16.
COMPRESSION FORCE
FIGURE 33–17 Combustion chamber pressure forces the ring against the cylinder wall and the bottom of the ring groove to effectively seal the cylinder.
FIGURE 33–19 This typical three-piece oil control ring uses a hump-type stainless steel spacer-expander. The expander separates the two steel rails and presses them against the cylinder wall.
BUTT GAP
BACK CLEARANCE
SIDE CLEARANCE
TAPERED GAP
SEAL CUT GAP
FIGURE 33–20 Typical piston ring gaps.
FIGURE 33–18 The side and back clearances must be correct for the compression rings to seal properly.
CLASSIFICATIONS
Piston rings are classified into two types.
1. Two compression rings, located toward the top of the piston 2. One oil control ring, located below the compression rings NOTE: Some engines, such as Honda high-fuel economy engines, use pistons with only two rings: one compression ring and one oil control ring.
Steel spring expanders were placed in the ring groove behind the ring to improve static radial tension. They forced the ring to conform to the cylinder wall. Many expander designs are used. On the three-piece ring, a spacer expander lies between the top and bottom rails. The spacer expander keeps the rails separated and pushes them out against the cylinder wall. SEE FIGURE 33–19.
RING GAP
The piston ring gap will allow some leakage past the top compression ring. This leakage is useful in providing pressure on the second ring to develop a dynamic sealing force. The amount of piston ring gap is critical.
Too much gap. A ring gap that is too great will allow excessive blowby. Blowby is the leakage of combustion gases past the rings. Blowby will blow oil from the cylinder wall. This oil loss is followed by piston ring scuffing.
Too little gap. A ring gap that is too little will allow the piston ring ends to touch together when the engine is hot. Ring end touching increases the mechanical force against the cylinder wall, causing excessive wear and possible engine failure.
COMPRESSION RINGS
A compression ring is designed to form a seal between the moving piston and the cylinder wall. This is necessary to get maximum power from the combustion pressure. At the same time, the compression ring must keep friction at a minimum. This is made possible by providing only enough static or built-in mechanical tension to hold the ring in contact with the cylinder wall during the intake stroke. Combustion chamber pressure during the compression, power, and exhaust strokes is applied to the top and back of the ring. This pressure will add extra force on the ring that is required to seal the combustion chamber during these strokes. FIGURE 33–17 illustrates how the combustion chamber pressure adds force to the ring. The space in the ring groove above the ring is called the side clearance and the space behind the ring is called the back clearance. SEE FIGURE 33–18.
OIL CONTROL RINGS
The scraping action of the oil control ring allows oil to return through the expander and openings in the piston.
A butt-type piston ring gap is the most common type used in automotive engines. Some low-speed industrial engines and some diesel engines use a more expensive tapered or seal-cut ring gap. These gaps are necessary to reduce losses of the high-pressure combustion gases. At low speeds, the gases have more time to leak through the gap. Typical ring gaps are illustrated in FIGURE 33–20.
PISTON RING SHAPES As engine speeds have increased, inertia forces on the piston rings have also increased. As a result, engine manufacturers have found it desirable to reduce inertia forces on the rings by reducing their weight. This has been done by
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TAPER FACE
FIGURE 33–21 The taper face ring provides oil control by scraping the cylinder wall. This style of ring must be installed right side up or the ring will not seal and oil will be drawn into the combustion chamber.
SCRAPER FACE
FIGURE 33–23 Scraper-type rings provide improved oil control.
LINE CONTACT ON BARREL-FACED RING
POSITIVE TORSIONAL TWIST
REVERSE TORSIONAL TWIST
LINE CONTACT ON TAPER-FACED RING
FIGURE 33–24 The upper barrel face ring has a line showing contact with the cylinder wall. The second taper face ring shows contact along the lower edge of the ring.
FIGURE 33–22 Torsional twist rings provide better compression sealing and oil control than regular taper rings.
Scraper ring does a good job of oil control and is usually recommended for use at the second compression ring.
Barrel face ring can replace the outer ring taper on some rings. The barrel is 0.0003 in. per 0.1 in. (0.0076 mm per 0.254 mm) of piston ring width. Barrel faces are found on rectangular rings and on torsionally twisted rings. SEE FIGURE 33–24.
reducing the thickness of the piston ring from 1/4 in. (6 mm) to as little as 1/16 in. (1.6 mm). There are several types of piston rings.
Taper face ring will contact the cylinder wall at the lower edge of the piston ring. SEE FIGURE 33–21. When either a chamfer or counterbore relief is made on the upper inside corner of the piston ring, the ring cross section is unbalanced, causing the ring to twist in the groove in a positive direction. Positive twist ring will give the same wall contact as the taper face ring. It will also provide a line contact seal on the bottom side of the groove. Sometimes, twist and a taper face are used on the same compression ring. Some second rings are notched on the outer lower corner. This, too, provides a positive ring twist. The sharp, lower outer corner becomes a scraper that helps in oil control, but this type of ring has less compression control than the preceding types. Reverse twist ring is produced by chamfering the ring’s lower inner corner. This seals the lower outer section of the ring and piston ring groove, thus improving oil control. Reverse twist rings require a greater taper face or barrel face to maintain the desired ring face-to-cylinder wall contact. SEE FIGURE 33–22. Another style of positive twist ring has a counterbore at the lower outside edge. SEE FIGURE 33–23.
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PISTON RING CONSTRUCTION PISTON RING MATERIALS The first piston rings were made with a simple rectangular cross section, modified with tapers, chamfers, counterbores, slots, rails, and expanders. Piston ring materials can include:
Plain cast iron
Pearlitic cast iron
Nodular cast iron
Steel
Ductile iron (This is also used as a piston ring material in some automotive engines, which is very flexible and can be twisted without breaking.)
CHROMIUM PISTON RINGS
A chromium facing on cast iron rings greatly increases piston ring life, especially where abrasive materials are present in the air. During manufacture, the chromium-plated
PISTON CHROME FACING
FIGURE 33–25 The chrome facing on this compression ring is about 0.004 in. (0.10 mm) thick.
MOLY FACING
WRIST PIN
CONNECTING ROD
ROD BOLT
ROD BEARINGS CONNECTING ROD CAP
FIGURE 33–26 The moly facing on this compression ring is about 0.005 in. (0.13 mm) thick.
FIGURE 33–27 The connecting rod is the most highly stressed part of any engine because combustion pressure tries to compress it and piston inertia tries to pull it apart.
ring is slightly chamfered at the outer corners. About 0.004 in. (0.01 mm) of chrome is then plated on the ring face. Chromium-faced rings are then prelapped or honed before they are packaged and shipped to the customer. The finished chromium facing is shown in a sectional view in FIGURE 33–25.
MOLYBDENUM PISTON RINGS
Early in the 1960s, molybdenum piston ring faces were introduced. These rings proved to have good service life, especially under scuffing conditions. The plasma method is a spray method used to deposit molybdenum on cast iron to produce a long-wearing and low-friction piston ring. The plasma method involves an electric arc plasma (ionized gas) that generates an extremely high temperature to melt the molybdenum and spraydeposit a molten powder of it onto a piston ring. Therefore, plasma rings are molybdenum (moly) rings that have the moly coating applied by the plasma method. Most molybdenum face piston rings have a groove that is 0.004 to 0.008 in. (0.1 to 0.2 mm) deep cut into the ring face. This groove is filled with molybdenum, using a metallic (or plasma) spray method, so that there is a cast iron edge above and below the molybdenum. This edge may be chamfered in some applications. A sectional view of a molybdenum face ring is shown in FIGURE 33–26. Molybdenum face piston rings will survive under high-temperature and scuffing conditions better than chromium face rings. Under abrasive wear conditions, chromium face rings will have a better service life. There is little measurable difference between these two facing materials with respect to blowby, oil control, break-in, and horsepower. Piston rings with either of these two types of facings are far better than plain cast iron rings with phosphorus coatings. A molybdenum face ring, when used, will be found in the top groove, and a plain cast iron or chromium face ring will be found in the second groove.
MOLY-CHROME-CARBIDE RINGS Rings with moly-chromecarbide coating are also used in some original equipment (OE) and replacement applications. The coating has properties that include the hardness of the chrome and carbide combined with the heat resistance of molybdenum. CERAMIC-COATED RINGS
The ceramic-coated ring surface is created by applying a ceramic coating to the ring using a process called physical vapor deposition (PVD). Ceramic-coated rings are
FIGURE 33–28 The I-beam shape (top rod) is the most common, but the H-beam shape is common in high-performance and racing engine applications. also being used where additional heat resistance is needed, such as in some heavy-duty, turbocharged, or supercharged engines. For example, the General Motors Duramax 6.6 liter diesel engine uses ceramic-coated rings.
CONNECTING RODS PURPOSE AND FUNCTION
The connecting rod transfers the force and reciprocating motion of the piston to the crankshaft. The small end of the connecting rod reciprocates with the piston. The large end rotates with the crankpin. SEE FIGURE 33–27. These dynamic motions make it desirable to keep the connecting rod as light as possible while still having a rigid beam section. SEE FIGURE 33–28. Connecting rods are manufactured by casting, forging, and powdered (sintered) metal processes.
CONNECTING ROD DESIGN
The big end of the connecting rod must be a perfect circle. Once a rod and cap are initially machined, they must remain a “matched set,” due to the precise machining required to obtain a perfect circle. Therefore, the rod caps must not be interchanged. Assembly bolt holes are closely
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BALANCE PAD
FIGURE 33–29 Rod bolts are quickly removed using a press. BALANCE PAD
reamed in both the cap and connecting rod to ensure alignment. The connecting rod bolts have piloting surfaces that closely fit these reamed holes. The fit of the connecting rod bolts is so tight that a press must be used to remove the bolts when they are to be replaced, as shown in FIGURE 33–29. In some engines, offset connecting rods provide the most economical distribution of main bearing space and crankshaft cheek clearance. Many connecting rods are made with balancing bosses (pads) so that their weight can be adjusted to specifications. Some have balancing bosses only on the rod cap. Others also have a balancing boss at the small end. Some manufacturers put balancing bosses on the side of the rod, near the center of gravity of the connecting rod. Typical balancing bosses can be seen in FIGURE 33–30. Balancing is done on automatic balancing machines as the final machining operation before the rod is installed in an engine. Some connecting rods have a spit hole that bleeds some of the oil from the connecting rod journal. SEE FIGURES 33–31 AND 33–32. On inline engines, oil is thrown up from the spit hole into the cylinder in which the rod is located. On V-type engines, it is often thrown into a cylinder in the opposite bank. The oil that is spit from the rod is aimed so that it will splash into the interior of the piston to help lubricate the piston pin. A hole similar to the spit holes may be used, called a bleed hole, to control the oil flow through the bearing.
CAST CONNECTING RODS Casting materials and processes have been improved so that they are used in most vehicle engines with high production standards. Cast connecting rods can be identified by their narrow parting line. A typical rough connecting rod casting is shown in FIGURE 33–33. FORGED CONNECTING RODS Forged connecting rods have been used for years. They are generally used in heavy-duty and high-performance engines. Generally, the forging method produces
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FIGURE 33–30 Some rods have balancing pads on each end of the connecting rod.
CYLINDER WALL
CONNECTING ROD
OIL HOLE
FIGURE 33–31 Some connecting rods have spit holes to help lubricate the cylinder wall or piston pin.
lighter weight and stronger but more expensive connecting rods. Forged connecting rods can be identified by their wide parting line. Many high-performance connecting rods use a bronze bushing in the small end as shown in FIGURE 33–34.
POWDERED METAL CONNECTING RODS
Most new production engines, including the General Motors Northstar, the Ford 4.6, 5.0, and 6.6 liter OHC V-8s, and the Chrysler Hemi, use powdered metal (PM) connecting rods. Powdered metal connecting rods have many advantages over convention cast or forged rods including precise weight control. Each rod is created using a measured amount of material so that rod
PISTON
OIL GALLERY
OIL SQUIRTER
OIL HOLE
BRONZE BUSHING
CONNECTING ROD
CRANKSHAFT
FIGURE 33–32 Some engines, such as this Ford diesel, are equipped with oil squirters that spray or stream oil toward the underneath side of the piston head to cool the piston.
FIGURE 33–34 This high-performance connecting rod uses a bronze bushing in the small end of the rod and oil hole to allow oil to reach the full-floating piston pin.
THIN PARTING LINE
CRACKED PARTING LINE
FIGURE 33–33 A cast connecting rod is found on many stock engines and can be identified by the thin parting line. balancing, and therefore engine balancing, is now achieved without extra weighting and machining operations.
Powdered metal connecting rods start as powdered metal, which includes iron, copper, carbon, and other alloying agents.
This powder is then placed in a die and compacted (forged) under a pressure of 30 to 50 tons per square inch.
After the part is shaped in the die, it is taken through a sintering operation where the part is heated, without melting, to about 2,000°F. During the sintering process, the ingredients are transformed into metallurgical bonds, giving the part strength.
Machining is very limited and includes boring the small and big end and drilling the holes for the rod bearing cap retaining bolts.
The big end is then fractured using a large press. The uneven parting line helps ensure a perfect match when the pieces are assembled. SEE FIGURE 33–35.
FIGURE 33–35 Powdered metal connecting rods feature a fractured parting line at the big end of the rod.
CONNECTING ROD SERVICE REMOVING PISTONS FROM RODS
The pistons are removed from the rods using a special fixture shown in FIGURE 33–36.
INSPECTION
Before connecting rod reconditioning, the rod should be checked for twist. SEE FIGURE 33–37. In other words, the hole at the small end and the hole at the big end of the connecting rod should be parallel. No more than a 0.002 in. (0.05 mm) twist is acceptable. SEE FIGURE 33–38 for the fixture used to check connecting rods for twist.
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FIGURE 33–39 Rod bearing bores normally stretch from top to bottom, with most wear concentrated on the rod cap. FIGURE 33–36 A press used to remove the connecting rod from the piston.
If measured rod twist is excessive, some specialty shops can remove the twist by bending the rod cold. Both cast and forged rods can be straightened. However, many engine builders replace the connecting rod if it is twisted.
RECONDITIONING PROCEDURE As an engine operates, the forces go through the large end of the connecting rod. This causes the crankshaft end opening of the rod (eye) to gradually deform. SEE FIGURE 33–39. The large eye of the connecting rod is resized during precision engine service. STEP 1
NOTE: Powdered metal connecting rods cannot be reconditioned using this method. Most manufacturers recommend replacing worn powdered metal connecting rods.
FIGURE 33–37 If the rod is twisted, it will cause diagonal-type wear on the piston skirt. SURFACE PLATE
STEP 2 BEND INDICATOR
The parting surfaces of the rod and cap are smoothed to remove all high spots before resizing. A couple of thousandths of an inch of metal is removed from the rod cap parting surface. This is done using the same grinder that is used to remove a slight amount of metal from the parting surface of main bearing caps. The amount removed from the rod and rod cap only reduces the bore size 0.003 to 0.006 in. (0.08 to 0.15 mm).
The cap is installed on the rod, and the nuts or cap screws are properly torqued. The hole is then bored or honed to be perfectly round and of the size and finish required to give the correct connecting rod bearing crush. FIGURE 33–40 shows the setup for resizing the rod on a typical hone used in engine reconditioning.
Even though material is being removed at the big end of the rod, the compression ratio is changed very little. The inside of the bore at the big end should have a 60 to 90 microinch finish for proper bearing contact and heat transfer.
PISTON AND ROD ASSEMBLY CONTACT BARS
CONNECTING ROD
FIGURE 33–38 A rod alignment fixture is used to check a connecting rod for bends or twists.
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INTERFERENCE FIT RODS
To assemble the piston and rod, the piston pin is put in one side of the piston. The small end of the connecting rod should be checked for proper size. The small eye of the connecting rod is heated before the pin is installed. SEE FIGURE 33–41.
FIGURE 33–40 To help ensure that the big ends are honed straight, many experts recommend placing two rods together when performing the honing operation.
FIGURE 33–42 The side clearance of the piston ring is checked with a feeler gauge.
the piston pin. The lock ring expands into a small groove in the pin hole of the piston. NOTE: The original lock rings should always be replaced with new rings.
PISTON RING SERVICE STEPS
Each piston ring, one at a time, should be placed backward in the groove in which it is to be run. STEP 1
Check side clearance. As the piston goes rapidly up and down in the cylinder, it tosses the rings to the top and to the bottom of the ring grooves. The pounding of each ring in its groove gradually increases the piston ring side clearance. Material is worn from both the ring and the groove. Replace the piston if the ring groove is larger than factory specifications. The side clearance in the groove should be checked with a feeler gauge, as shown in FIGURE 33–42.
STEP 2
Check ring gap. After the block and cylinder bores have been reconditioned, invert the piston and push each ring into the lower quarter of the cylinder; then measure the ring gap. SEE FIGURE 33–43. The usual ring gap should be approximately 0.004 in. for each inch of bore diameter (0.004 mm for each centimeter of bore diameter). The second ring also needs to have a similar or even larger end gap. • If excessive ring gap is present, the blowby gases can enter the crankcase. Replace the ring(s) if the gap is too large. • If the gap is too narrow, use a file or hand-operated piston ring grinder to achieve the necessary ring gap. SEE FIGURE 33–44.
STEP 3
Installing the oil control ring. The oil rings are installed first. The expander-spacer of the oil ring is placed in the lower ring groove. One oil ring rail is carefully placed above the expander-spacer by winding it into the groove. The other rail is placed below the expander-spacer. The ring should be rotated in the groove to ensure that the expander-spacer ends have not overlapped. If they have, the ring must be removed and reassembled correctly.
FIGURE 33–41 The small end of the rod is being heated in an electric heater and the piston is positioned properly so the piston pin can be installed as soon as the rod is removed from the heater. This causes the rod eye to expand so that the pin can be pushed into place with little force. The pin must be rapidly pushed into the correct center position. There is only one chance to get it in the right place because the rod will quickly seize on the pin as the rod eye is cooled by the pin.
FULL-FLOATING RODS Full-floating piston pins operate in a bushing in the small eye of the connecting rod. The bushing can be replaced. The bushing and the piston are honed to the same diameter. This allows the piston pin to slide freely through both. The full-floating piston pin is held in place with a lock ring at each end of
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FEELER GAUGE
FIGURE 33–45 A typical ring expander being used to install a piston ring on a piston.
PISTON RING
FIGURE 33–43 The ring gap is measured using a feeler gauge.
TOP
T
FIGURE 33–46 Identification marks used to indicate the side of the piston ring to be placed toward the head of the piston. STEP 4
Installing the compression rings. Installing the compression rings requires the use of a piston ring expander tool that will only open the ring gap enough to slip the ring on the piston. SEE FIGURE 33–45. Be careful to install the ring with the correct side up. The top of the compression ring is marked with one of the following: • One dot • The letter T • The word top
SEE FIGURE 33–46. FIGURE 33–44 A hand-operated piston ring end gap grinder being used to increase the end gap of a piston ring so that it is within factory specifications.
STEP 5
Double-check everything. After the rings are installed they should be rotated in the groove to ensure that they move freely, and checked to ensure that they will go fully into the groove so that the ring face is flush with the surface of the piston ring lands. Usually, the rings are placed on all pistons before any pistons are installed in the cylinders.
REVIEW QUESTIONS 2. Why are some piston skirts tin plated?
5. What causes the piston ring groove clearance to widen in service?
3. How does piston pin offset control piston slap?
6. List the steps needed to recondition connecting rods.
4. Why are forged pistons recommended for use in highperformance engines?
7. How is the piston pin installed in the piston and rod assembly?
1. List the methods used to control piston heat expansion.
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CHAPTER QUIZ 1. A hypereutectic piston ______________. a. Uses about 16% silicon c. Is a forged piston b. Is a cast piston d. Both a and b
6. The space behind the ring is called ______________. a. Side clearance c. Back clearance b. Forward clearance d. Piston ring clearance
2. Many aluminum piston skirts are plated with ______________. a. Tin or moly graphite c. Antimony b. Lead d. Terneplate
7. A misaligned connecting rod causes what type of engine wear? a. Cylinder taper b. Barrel shape cylinders c. Ridge wear d. Diagonal wear on the piston skirt
3. A hypereutectic piston has a higher ______________. a. Weight than an aluminum piston b. Silicon content c. Tin content d. Nickel content 4. The purpose of casting steel struts into an aluminum piston is to ______________. a. Provide increased strength b. Provide increased weight at the top part of the piston where it is needed for stability c. Control thermal expansion d. Both a and c 5. Full-floating piston pins are retained by ______________. a. Lock rings b. A drilled hole with roll pin c. An interference fit between rod and piston pin d. An interference fit between piston and piston pin
chapter
8. Side clearance is a measure taken between the ______________ and the ______________. a. Piston (side skirt); cylinder wall b. Piston pin; piston pin retainer (clip) c. Piston ring; piston ring groove d. Compression ring; oil control ring 9. Piston ring gap should only be measured after ______________. a. All cylinder work has been performed b. Installing the piston in the cylinder c. Installing the rings on the piston d. Both a and c 10. Which type of connecting rod needs to be heated to install the piston pin? a. Forged c. Floating b. Interference fit d. PM rods
ENGINE BLOCKS
34 OBJECTIVES: After studying Chapter 34, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “C” (Engine Block Diagnosis and Repair). • Describe the types of engine blocks and how they are manufactured. • Measure cylinder bores. • Discuss the machining operations required on most engine blocks. • List the steps necessary to prepare an engine block for assembly. KEY TERMS: Bedplate 353 • Block deck 353 • Bores 352 • Compacted graphite iron (CGI) 353 • Cooling jacket 354 • Core plugs 352 • Crosshatch finish 361 • Decking the block 357 • Dry cylinder sleeve 353 • Fiber-reinforced matrix (FRM) 354 • Freeze plugs 352 • Frost plugs 352 • Girdle 355 • Grit size 361 • Monoblock 352 • Oil gallery 354 • Oil gallery plugs 354 • Plateau honing 360 • Saddles 356 • Siamese cylinder bores 354 • Sleeving 359 • Wet cylinder sleeve 353
ENGINE BLOCKS CONSTRUCTION
The engine block, which is the supporting structure for the entire engine, is made from one of the following:
Cast iron contains about 3% carbon (graphite), which makes it gray in color. Steel is iron with most of the carbon removed. The carbon in cast iron makes it hard but brittle. Cast iron is used to make engine blocks and cylinder heads for the following reasons.
The carbon in the cast iron allows for easy machining, often without coolant.
Cast aluminum
The graphite in the cast iron also has lubricating properties.
Die-cast aluminum alloy
Cast iron is strong for its weight and usually is magnetic.
Gray cast iron
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CYLINDER HEAD BOLT HOLE CORE PLUG
CYLINDER BORE DECK SURFACE
CORE PLUG
CRANKCASE
FIGURE 34–2 An expansion (core) plug is used to block the opening in the cylinder head or block the holes where the core sand was removed after the part was cast.
FIGURE 34–1 The cylinder block usually extends from the oil pan rails at the bottom to the deck surface at the top.
The liquid cast iron is poured into a mold made from either sand or Styrofoam. All other engine parts are mounted on or in the block. This large casting supports the crankshaft and camshaft (on OHV engines) and holds all the parts in alignment. Newer blocks use thinner walls to reduce weight. Blocks are often of the monoblock design, which means that the cylinder, water jacket, main bearing supports (saddles), and oil passages are all cast as one structure for strength and quietness. Large-diameter holes in the block casting form the cylinders to guide the pistons. The cylinder holes are called bores because they are made by a machining process called boring. SEE FIGURE 34–1. Combustion pressure loads are carried from the head to the crankshaft bearings through the block structure. The block has webs, walls, and drilled passages to contain the coolant and lubricating oil and to keep them separated from each other. Mounting pads or lugs on the block transfer the engine torque reaction to the vehicle frame through attached engine mounts. A large mounting surface at the rear of the engine block is used for fastening a bell housing or transmission. The cylinder head(s) and other components attach to the block. The joints between the components are sealed using gaskets or sealants. Gaskets or sealants are used in the joints to take up differences that are created by machining irregularities and that result from different pressures and temperatures.
BLOCK MANUFACTURING Cast-iron cylinder block sand casting technology continues to be improved. The trend is to make blocks with larger cores, using fewer individual pieces. Oil-sand cores are forms that shape the internal openings and passages in the engine block. Before casting, the cores are supported within a core box. The core box also has a liner to shape the outside of the block. Special alloy cast iron is poured into the box. It flows between the cores and the core box liner. As the cast iron cools, the core breaks up. When the cast iron has hardened, it is removed from the core box, and the pieces of sand core are removed through the openings in the block by vigorously shaking the casting. These openings in the block are plugged with core plugs. Core plugs are also called freeze plugs or frost plugs. Although the name seems to mean that the plugs would be pushed outward if the coolant in
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FIGURE 34–3 A Styrofoam casting mold used to make the five cylinder engine blocks for the Chevrolet Colorado and the Hummer H3. The brown lines are glue used to hold the various parts together. Sand is packed around the mold and molten aluminum is poured into the sand which instantly vaporizes the Styrofoam. The aluminum then flows and fills the area of the mold.
the passages were to freeze, they seldom work this way. SEE FIGURE 34–2. One way to keep the engine weight as low as possible is to make the block with minimum wall thickness. The cast iron used with thin-wall casting techniques has higher nickel content and is harder than the cast iron previously used. Engine designers have used foundry techniques to make engines lightweight by making the cast-iron block walls and bulkheads only as heavy as necessary to support their required loads.
ALUMINUM BLOCKS
Aluminum is used for some cylinder blocks and is nonmagnetic and lightweight. Styrofoam is often used as a core when casting an aluminum block. The Styrofoam vaporizes as soon as the molten aluminum comes in contact with the foam leaving behind a cavity where the aluminum flows. SEE FIGURE 34–3. Aluminum block engines usually require cast-iron cylinder walls for proper wear and longevity. Aluminum blocks may have one of several different types of cylinder walls.
DECK SURFACE FOR HEAD GASKET
CAST IRON CYLINDER SLEEVES
ALUMINUM BLOCK
DRY CYLINDER SLEEVE
FIGURE 34–4 Cast-iron dry sleeves are used in aluminum blocks to provide a hard surface for the rings.
?
WATER JACKETS
CYLINDER BLOCK
WET CYLINDER SLEEVE
SEAL
FIGURE 34–5 A dry sleeve is supported by the surrounding cylinder block. A wet sleeve must be thicker to be able to withstand combustion pressures without total support from the block.
FREQUENTLY ASKED QUESTION
What Is Compacted Graphite Iron? Compacted graphite iron (CGI) has increased the strength, ductility, toughness, and stiffness compared to gray iron. If no magnesium is added, the iron will form gray iron when cooled, with the graphite present in flake form. If a very small amount of magnesium is added, more and more of the sulfur and oxygen form in the molten solution, and the shape of the graphite begins to change to compacted graphite forms. Compacted graphite iron is used for bedplates and many diesel engine blocks. It has higher strength, stiffness, and toughness than gray iron. The enhanced strength has been shown to permit reduced weight while still reducing noise vibration and harshness. Compacted graphite iron is commonly used in the blocks of diesel and some high-performance engines.
Most cast-aluminum blocks have cast-iron cylinder sleeves (liners) such as Saturn, Northstar, and Ford modular V-8s and V-6s. The cast-iron cylinder sleeves are either cast into the aluminum block during manufacturing or pressed into the aluminum block. These sleeves are not in contact with the coolant passages and are called dry cylinder sleeves. SEE FIGURE 34–4.
Another aluminum block design has the block die cast from silicon-aluminum alloy with no cylinder liners. Pistons with zinc-copper-hard iron coatings are used in these aluminum bores (in some Porsche engines).
Some engines have die-cast aluminum blocks with replaceable cast-iron cylinder sleeves. The sleeves are sealed at the block deck and at their base. Coolant flows around the cylinder sleeve, so this type of sleeve is called a wet cylinder sleeve (in Cadillac 4.1, 4.5, and 4.9 liter V-8 engines). SEE FIGURE 34–5.
Cast-iron main bearing caps are used with aluminum blocks to give the required strength.
BEDPLATE DESIGN BLOCKS
A bedplate is a structural member that attaches to the bottom of the block and supports the crankshaft. The oil pan is mounted under the bedplate which in most
FIGURE 34–6 A bedplate is a structural part of the engine which is attached between the block and the oil pan and supports the crankshaft. cases is also part of the structure and support for the block assembly. SEE FIGURE 34–6.
CASTING NUMBERS Whenever an engine part such as a block is cast, a number is put into the mold to identify the casting. These casting numbers can be used to check dimensions, such as the cubic inch displacement, and other information, such as year of manufacture. Sometimes changes are made to the mold, yet the casting number is not changed. Most often the casting number is the best piece of identifying information that the service technician can use. SEE FIGURE 34–7. BLOCK DECK The cylinder head is fastened to the top surface of the block. This surface is called the block deck. The deck has a smooth surface to seal against the head gasket. Bolt holes are positioned around the cylinders to form an even holding pattern. Four, five, or six head bolts are used around each cylinder in automobile engines. These bolt holes go into reinforced areas within the block that carry the combustion pressure load to the main bearing bulkheads.
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Additional holes in the block are used to transfer coolant and oil, as seen in FIGURE 34–8.
COOLING PASSAGES
Cylinders are surrounded by cooling passages. These coolant passages around the cylinders are often called the cooling jacket. In most cylinder designs, the cooling passages extend nearly to the bottom of the cylinder. In some engine blocks where the block ends at the centerline of the crankshaft, the cooling passages are limited to the upper portion of the cylinder.
?
FREQUENTLY ASKED QUESTION
What Are FRM-Lined Cylinders? Fiber-reinforced matrix (FRM) is used to strengthen cylinder walls in some Honda/Acura engines. FRM is a ceramic material similar to that used to construct the insulators of spark plugs. The lightweight material has excellent wear resistance and good heat transfer properties, making it ideal for use as a cylinder material. FRM inserts are placed in the mold and the engine block is cast over them. The inserts are rough and can easily adhere to the engine block. The inserts are then bored and honed to form the finished cylinders. FRM blocks were first used in a production engine on the Honda S2000 and are also used on the turbocharged Acura RDX sport utility vehicle.
FIGURE 34–7 Casting numbers identify the block.
Some engines are built with Siamese cylinder bores where the cylinder walls are cast together without a water jacket (passage) between the cylinders. While this design improves the strength of the block and adds stability to the cylinder bores, it can reduce the cooling around the cylinders. FIGURE 34–9 is a typical V-8 engine cutaway that shows the coolant jackets and some of the lubrication holes.
LUBRICATING PASSAGES
An engine block has many oil holes that carry lubricating oil to the required locations. During manufacture, all oil holes, called the oil gallery, are drilled from outside the block. When a curved passage is needed, intersecting straight drilled holes are used. In some engines, plugs are placed in the oil holes to direct oil to another point before it comes back to the original hole, on the opposite side of the plug. After oil holes are drilled, the unneeded open ends may be capped by pipe plugs, steel balls, or cup-type soft plugs, often called oil gallery plugs. These end plugs in the oil passages can be a source of oil leakage in operating engines. SEE FIGURE 34–10.
TECH TIP What Does LHD Mean? The abbreviation LHD means left-hand dipstick, which is commonly used by rebuilders and remanufacturers in their literature in describing Chevrolet small block V-8 engines. Before about 1980, most small block Chevrolet V-8s used an oil dipstick pad on the left side (driver’s side) of the engine block. Starting in about 1980, when oxygen sensors were first used on this engine, the dipstick was relocated to the right side of the block. Therefore, to be assured of ordering or delivering the correct engine, knowing the dipstick location is critical. An LHD block cannot be used with the exhaust manifold setup that includes the oxygen sensor without major refitting or the installing of a different style of oil pan that includes a provision for an oil dipstick. Engine blocks with the dipstick pad cast on the right side are, therefore, coded as right-hand dipstick (RHD) engines. NOTE: Some blocks cast around the year 1980 are cast with both right- and left-hand oil dipstick pads, but only one is drilled for the dipstick tube. SEE FIGURE 34–11.
CYLINDER BORE DECK SURFACE
LIFTER BORE OIL GALLERIES
COOLANT PASSAGES
FIGURE 34–8 The deck is the machined top surface of the block.
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CYLINDER BORES
MAIN BEARING SADDLE WEB
FIGURE 34–9 Cutaway of a Chevrolet V-8 block showing all of the internal passages.
STUD OIL GALLERY PLUGS BOLT
REAR CAP
CAP CAP CAP CAMSHAFT CUP PLUG
FIGURE 34–10 Typical oil gallery plugs on the rear of a Chevrolet small block V-8 engine.
THRUST BEARING INSERT
MAIN BEARING INSERT
MAIN BEARING INSERT
CRANKSHAFT
THRUST BEARING INSERT CYLINDER BLOCK
LEFT-HAND DIPSTICK
RIGHT-HAND PAD
FRONT
FIGURE 34–12 Two-bolt main bearing caps provide adequate bottom end strength for most engines.
FOUR-BOLT MAIN BEARING CAP
FIGURE 34–11 Small block Chevrolet block. Note the left-hand dipstick hole and a pad cast for a right-hand dipstick.
MAIN BEARING CAPS
The main bearing caps are cast or manufactured from sintered or billeted materials, separately from the block.
They are machined and then installed on the block for a final bore finishing operation.
With caps installed, the main bearing bores and cam bearing bores (on OHV engines) are machined to the correct size and alignment. On some engines, these bores are honed to a very fine finish and exact size.
Main bearing caps are not interchangeable or reversible, because they are individually finished in place.
Main bearing caps may have cast numbers indicating their position on the block. If not, they should be marked with numbers and arrows pointing toward the front of the engine.
Standard production engines usually use two bolts to hold the main bearing cap in place. SEE FIGURE 34–12.
FIGURE 34–13 High-performance and truck engines often use four-bolt main bearing caps for greater durability.
Heavy-duty and high-performance engines often use additional main bearing support bolts. A four-bolt, and even six-bolt, main cap can be of a cross-bolted design in a deep skirt block or of a parallel design in a shallow skirt block. SEE FIGURES 34–13 AND 34–14. Expansion force of the combustion chamber gases will try to push the head off the top and the crankshaft off the bottom of the block. The engine is held together with the head bolts and main bearing cap bolts screwed into bolt bosses and ribs in the block. The extra bolts on the main bearing cap help to support the crankshaft when there are high combustion pressures and mechanical loads, especially during high engine speed operation. Many engines use a girdle which ties all of the main bearing caps together to add strength to the lower part of the block. SEE FIGURE 34–15.
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STUDS SCREW INTO BLOCK
WARPED MAIN BEARING BORE CENTERLINE
BEARING CAP
ORIGINAL MAIN BEARING BORE CENTERLINE
FIGURE 34–16 The main bearing bores of a warped block usually bend into a bowed shape. The greatest distortion is in the center bores.
CROSS BOLT
WARPED BORE ORIGINAL BORE
CROSS BOLT
OUT-OFROUND
FIGURE 34–14 Some engines add to the strength of a four-bolt main bearing cap by also using cross bolts through the bolt on the sides of the main bearing caps.
GIRDLE
PINCHED IN
FIGURE 34–17 When the main bearing caps bow downward, they also pinch in at the parting line.
MAIN BEARING HOUSING BORE ALIGNMENT
FIGURE 34–15 A girdle is used to tie all of the main bearing caps together.
ENGINE BLOCK SERVICE PROCEDURES
The engine block is the foundation of the engine. All parts of the block must be of the correct size and they must be aligned. The parts must also have the proper finishes if the engine is to function dependably for a normal service life. Engine blueprinting is the reconditioning of all the critical surfaces and dimensions so that the block is actually like new. After a thorough cleaning, the block should be inspected for cracks or other flaws before machine work begins. After the block has been cleaned and the cracked checked, the block should be prepared in the following sequence. OPERATION 1
Main bearing housing bore alignment, often called “align boring” (or honing)
OPERATION 2
Machining of the block deck surface parallel to the crankshaft
OPERATION 3
Cylinder boring and honing
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The main bearing journals of a straight crankshaft are in alignment. If the main bearing housing bores in the block are not in alignment, the crankshaft will bend as it rotates. This condition increases rotational friction of the crankshaft and will lead to premature bearing failure or a broken crankshaft. The original stress in the block casting is gradually relieved as the block is used. Some slight warpage may occur as the stress is relieved. In addition, the continued pounding caused by combustion will usually cause some stretch in the main bearing caps. SEE FIGURE 34–16. The main bearing bores gradually bow upward and elongate vertically. This means that the bearing bore becomes smaller at the centerline as the block distorts, pinching the bore inward at the sides. SEE FIGURE 34–17. The procedure includes the following steps.
STEP 1
The first step in determining the condition of the main bearing bores is to determine if the bore alignment in the block is straight. These bores are called the saddles. A precision ground straightedge and a feeler gauge are used to determine the amount of warpage. The amount of variation along the entire length of the block should not exceed 0.0015 in. (0.038 mm). CAUTION: When performing this measurement, be sure that the block is resting on a flat surface. If the engine is mounted to an engine stand, the weight of the block on the unsupported end can cause an error in the measurement of the main bearing bores and saddle alignment.
PRECISION STRAIGHTEDGE
FIGURE 34–18 The main bearing bore alignment can be checked using a precision straightedge and a feeler gauge.
?
(a)
FREQUENTLY ASKED QUESTION
What Is a Seasoned Engine? A new engine is machined and assembled within a few hours after the heads and block are cast from melted iron. Newly cast parts have internal stresses within the metal. The stress results from the different thickness of the metal sections in the head. Forces from combustion in the engine, plus continued heating and cooling, gradually relieve these stresses. By the time the engine has accumulated 20,000 to 30,000 miles (32,000 to 48,000 km), the stresses have been completely relieved. This is why some engine rebuilders prefer to work with used heads and blocks that are stress relieved. Used engines are often called “seasoned” because of the reduced stress and movement these components have as compared with new parts.
STEP 2
STEP 3
If the block saddles exceed one-and-a-half thousandth of an inch distortion, then align honing is required to restore the block. If the block saddles are straight, the bores should be measured to be sure that the bearing caps are not distorted. SEE FIGURE 34–18. The bearing caps should be installed and the retaining bolts tightened to the specified torque before measuring the main bearing bores. Using a telescoping gauge, measure each bore in at least two directions. Check the service information for the specified main bearing bore diameter. The bearing bore should not vary by more than one-half of a thousandth of an inch or 0.0005 in. (0.0127 mm). A dial bore gauge is often used to measure the main bearing bore. Set up the dial bore gauge in the fixture with the necessary extensions to achieve the nominal main bearing bore diameter. Check the service information for the specified main bearing bore diameter and determine the exact middle of the range.
ARBOR CHECK METHOD
The arbor is installed, then all main caps are tightened to specifications. After tightening, the arbor is checked to make sure it rotates freely, indicating a true centerline. However, because of all the different diameters required, it is an expensive method. SEE FIGURE 34–19.
(b)
FIGURE 34–19 (a) A precision arbor can be used to check the main bearing bore alignment. (b) If the sleeve can be inserted into all of the main bearing bores, then they are aligned.
MACHINING THE DECK SURFACE OF THE BLOCK An engine should have the same combustion chamber size in each cylinder. For this to occur, each piston must come up an equal distance from the block deck. The connecting rods are attached to the rod bearing journals of the crankshaft. Pistons are attached to the connecting rods. As the crankshaft rotates, the pistons come to the top of the stroke. When all parts are sized equally, all the pistons will come up to the same level. This can only happen if the block deck is parallel to the main bearing bores. Therefore, the flatness of the block deck should be checked. SEE FIGURE 34–20. The block deck must be resurfaced in a surfacing machine that can control the amount of metal removed when it is necessary to match the size of the combustion chambers. This procedure is called decking the block. The block is set up on a bar located in the main bearing saddles, or set up on the oil pan rails of the block. The bar is parallel to the direction of cutting head movement. The block is leveled sideways, and then the deck is resurfaced in the same manner as the head is resurfaced. FIGURE 34–21 shows a block deck being resurfaced by grinding.
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RING RIDGE
DECK SURFACE
POCKET
TAPERED CYLINDER WALL
UNWORN CYLINDER WALL
(a)
FIGURE 34–22 Cylinders wear in a taper, with most of the wear occurring at the top of the cylinder where the greatest amount of heat and pressure are created. The ridge is formed because the very top part of the cylinder is not contacted by the rings. (b)
FIGURE 34–20 (a) Checking the flatness of the block deck surface using a straightedge and a feeler gauge. (b) To be sure that the top of the block is flat, check the block in six locations as shown.
FIGURE 34–21 Grinding the deck surface of the block.
DECK SURFACE FINISH
The surface finish of the block deck
should be:
60 to 100 Ra (65 to 110 RMS) for cast iron
50 to 60 Ra (55 to 65 RMS) for aluminum block decks to be assured of a proper head gasket surface
The surface finish is determined by the type of grinding stone used, as well as the speed and coolant used in the finishing operation. The higher the surface finish number is, the rougher the surface.
CYLINDER BORING Cylinders should be measured across the engine (perpendicular to the crankshaft), where the greatest wear occurs. In other words, measure the bores at 90 degrees to the piston pin. Most wear will be found just below the ridge, and the least amount of wear will occur below the lowest ring travel. SEE FIGURE 34–22.
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FIGURE 34–23 Using a dial bore gauge to measure the bore diameter at the top just below the ridge (maximum wear section) and at the bottom below the ring travel (minimum wear section). The difference between these two measurements is the amount of cylinder taper. Take the measurements in line with the crankshaft and then repeat the measurements at right angles to the centerline of the block in each cylinder to determine out-of-round.
The cylinder should be checked for out-of-round and taper.
SEE FIGURE 34–23. Most cylinders are serviceable if they:
Are a maximum of 0.003 in. (0.076 mm) out-of-round
Have no more than a 0.005 in. (0.127 mm) taper
Have no deep scratches in the cylinder wall
NOTE: Always check the specifications for the engine being serviced. For example, the General Motors 4.8, 5.3, 5.7, 6, and 6.2 liter LS series V-8s have a maximum out-of-round of only 0.0003 in. (3/10 of one-thousandths of an inch). This specification is about one-third of the normal dimension of about 0.001 in.
CYLINDER BORING MACHINE CUTTER
The most effective way to correct excessive cylinder out-ofround, taper, or scoring is to rebore the cylinder. The rebored cylinder requires the use of a new, oversize piston. The maximum bore oversize is determined by two factors. 1. Cylinder wall thickness—at least 0.17 in. for street engines and 0.2 in. for high-performance or racing applications 2. Size of the available oversize pistons If in doubt as to the amount of overbore that is possible without causing structural weakness, an ultrasonic test should be performed on the block to determine the thickness of the cylinder walls. An ultrasonic tester can measure the thickness of the cylinder walls and is used to determine if a cylinder can be bored oversize and, if so, by how much. All cylinders should be tested. Variation in cylinder wall thickness occurs because of core shifting (moving) during the casting of the block. For best results, cylinders should be rebored to the smallest size possible.
FIGURE 34–24 A cylinder boring machine is used to enlarge cylinder bore diameter so a replacement oversize piston can be used to restore a worn engine to useful service or to increase the displacement of the engine in an attempt to increase power output.
HINT: The pistons that will be used should always be in hand before the cylinders are rebored. The cylinders are then bored and honed to match the exact size of the pistons. The cylinder must be perpendicular to the crankshaft for normal bearing and piston life. If the block deck has been aligned with the crankshaft, it can be used to align the cylinders. Portable cylinder boring bars are clamped to the block deck. Heavy-duty production boring machines support the block on the main bearing bores. Main bearing caps should be torqued in place when cylinders are being rebored. In precision boring, a torque plate is also bolted on in place of the cylinder head while boring cylinders. In this way, distortion is kept to a minimum. The general procedure used for reboring cylinders includes the following steps. STEP 1
Set the boring bar up so that it is perpendicular to the crankshaft. It must be located over the center of the cylinder.
STEP 2
The cylinder center is found by installing centering pins in the bar.
STEP 3
The bar is lowered so that the centering pins are located near the bottom of the cylinder, where the least wear has occurred. This locates the boring bar over the original cylinder center. Once the boring bar is centered, the boring machine is clamped in place to hold it securely. This will allow the cylinder to be rebored on the original centerline, regardless of the amount of cylinder wear.
STEP 4
A sharp, properly ground cutting tool is installed and adjusted to the desired dimension. Rough cuts remove a great deal of metal on each pass of the cutting tool. The rough cut is followed by a fine cut that produces a much smoother and more accurate finish. Different-shaped tool bits are used for rough and finish boring.
STEP 5
The last cut is made to produce a diameter that is at least 0.002 in. (0.05 mm) smaller than the required diameter. SEE FIGURE 34–24.
SLEEVING THE CYLINDER
Sometimes, cylinders have a gouge so deep that it will not clean up when the cylinder is rebored to the maximum size. This could happen if the piston pin moved
CAST IRON CYLINDER SLEEVE BEING INSTALLED IN BLOCK
CAST IRON BLOCK
FIGURE 34–25 A dry cylinder sleeve can also be installed in a cast-iron block to repair a worn or cracked cylinder.
endways and rubbed on the cylinder wall. Cylinder blocks with deep gouges may be able to be salvaged by sleeving the cylinder. The cylinder wall thickness has to be checked to see if sleeving is possible. Sleeving a cylinder is done by boring the cylinder to a dimension that is greatly oversize to almost match the outside diameter of the cylinder sleeve. The sleeve is pressed into the rebored block and then the center of the sleeve is bored to the diameter required by the piston. The cylinder can be sized to use a standard-size piston when it is sleeved. SEE FIGURE 34–25.
CYLINDER HONING
It is important to have the proper surface finish on the cylinder wall for the rings to seat against. Honing includes two basic operations depending on the application. 1. When installing new piston rings on a cylinder that is not being bored, some ring manufacturers recommend breaking the hard surface glaze on the cylinder wall with a hone before installing new piston rings. This process is often called “deglazing” the cylinder walls. 2. The cylinder wall should be honed to straighten the cylinder when the wall is wavy or scuffed. If honing is being done with the crankshaft remaining in the block, the crankshaft should be protected to keep honing chips from getting on the shaft.
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Two types of hones are used for cylinder service.
A deglazing hone removes the hard surface glaze remaining in the cylinder. It is a flexible hone that follows the shape of the cylinder wall, even when the wall is wavy. It cannot be used to straighten the cylinder. A brush-type (ball-type) deglazing hone is shown in FIGURE 34–26. A sizing hone can be used to straighten the cylinder and to provide a suitable surface for the piston rings. Honing the cylinder removes the fractured metal that is created by boring. The cylinders must be honed a minimum of 0.002 in. (0.05 mm) after boring to cut below the rough surface and provide an adequate finish. Honing leaves a plateau surface that can support the oil film for the rings and piston skirt. This plateau surface is achieved by
?
FREQUENTLY ASKED QUESTION Always Use Torque Plates
An easy way to calculate oversize piston size is to determine the amount of taper, double it, and add 0.010 in. (Taper 2 0.010 in. Oversize piston). Common oversize measurements include: 0.020 in. 0.030 in. 0.040 in. 0.060 in.
Use caution when boring for an oversize measurement larger than 0.030 in. due to potential engine damage caused from too thin cylinder walls.
?
Its honing stones are held in a rigid fixture with an expanding mechanism to control the size of the hone. The sizing hone can be used to straighten the cylinder taper by honing the lower cylinder diameter more than the upper diameter. As it rotates, the sizing hone only cuts the high spots so that cylinder out-of-round is also reduced. The cylinder wall surface finish is about the same when the cylinder is refinished with either type of hone. SEE FIGURE 34–28.
TECH TIP
How Do I Determine What Oversize Bore Is Needed?
• • • •
first using a coarse stone followed by a smooth stone to achieve the desired surface. The process of using a coarse and fine stone is called plateau honing. SEE FIGURE 34–27.
Torque plates are thick metal plates that are bolted to the cylinder block to duplicate the forces on the block that occur when the cylinder head is installed. Even though not all machine shops use torque plates during the boring operation, the use of torque plates during the final dimensional honing operation is beneficial. Without torque plates, cylinders can become out-of-round (up to 0.003 in.) and distorted when the cylinder heads are installed and torqued down. Even though the use of torque plates does not eliminate all distortion, their use helps to ensure a truer cylinder dimension. SEE FIGURE 34–29.
ROUGH-BORED TO 4.025 INCHES
FREQUENTLY ASKED QUESTION
CRACKS AND PITS TO 0.001 INCH
What Is a Boring Hone?
TARGET DIAMETER 4.030 INCHES
CYLINDER WALL AFTER BORING
Many shops now use “boring” hones instead of boring bars. Boring hones have the advantages of being able to resize and finish hone with only one machine setup. Often a diamond hone is used and rough honed to within about 0.003 in. of the finished bore size. Then a finish hone is used to provide the proper surface finish.
FIGURE 34–26 An assortment of ball-type deglazing hones. This type of hone does not straighten wavy cylinder walls.
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FIGURE 34–27 After boring, the cylinder surface is rough, pitted, and fractured to a depth of about 0.001 in.
ORIGINAL SURFACE BORED TO 4.025 INCHES
CROSS-HATCH PATTERN
FINISH HONING REMOVES 0.0025 INCH FROM EACH SIDE
CYLINDER WALL AFTER BORING
FINAL HONED DIAMETER 4.030 INCHES
50° ANGLE
FIGURE 34–30 The crosshatched pattern holds oil to keep the rings from wearing excessively, and also keeps the rings against the cylinder wall for a gas-tight fit. TECH TIP Bore to Size, Hone for Clearance
FIGURE 34–28 Honing enlarges the cylinder bore to the final size and leaves a plateau surface finish that retains oil.
Many engine rebuilders and remanufacturers bore the cylinders to the exact size of the oversize pistons that are to be used. After the block is bored to a standard oversize measurement, the cylinder is honed. The rigid hone stones, along with an experienced operator, can increase the bore size by 0.001 to 0.003 in. (one to three thousandths of an inch) for the typical clearance needed between the piston and the cylinder walls. For example: Actual piston diameter 4.028 in. Bore diameter 4.028 in. Diameter after honing 4.030 in. Amount removed by honing 0.002 in. NOTE: The minimum amount recommended to be removed by honing is 0.002 in., to remove the fractured metal in the cylinder wall caused by boring.
more rapidly in the cylinder. A typical honed cylinder is pictured in FIGURE 34–30.
CYLINDER SURFACE FINISH
FIGURE 34–29 A torque plate being used during a cylinder honing operation. The thick piece of metal is bolted to the block and simulates the forces exerted on the block by the head bolts when the cylinder head is attached. The hone is stroked up and down in the cylinder as it rotates to produce a crosshatch finish on the cylinder wall which aides in proper ring break-in. The speed that the operator moves the hone up and down controls the angle. Always check service information for the specified crosshatch angle. The angle of the crosshatch should be between 20 and 60 degrees. Higher angles are produced when the hone is stroked
The size of the abrasive particles in the grinding and honing stones controls the surface finish. The size of the abrasive is called the grit size. The abrasive is sifted through a screen mesh to sort out the grit size. A coarsemesh screen has few wires in each square inch, so large pieces can fall through the screen. A fine-mesh screen has many wires in each square inch so that only small pieces can fall through. The screen is used to separate the different grit sizes. The grit size is the number of wires in each square inch of the mesh. A low-numbered grit has large pieces of abrasive material; a highnumbered grit has small pieces of abrasive material. The higher the grit number is, the smoother the surface finish will be. SEE CHART 34–1. A given grit size will produce the same finish as long as the cutting pressure is constant. With the same grit size, light cutting
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GRIT SIZING CHART GRIT/SIEVE SIZE
INCHES
MILLIMETERS
12
0.063
1.600
16
0.043
1.092
20
0.037
0.939
24
0.027
0.685
30
0.022
0.558
36
0.019
0.482
46
0.014
0.355
54
0.012
0.304
60
0.010
0.254
70
0.008
0.203
80
0.0065
0.165
90
0.0057
0.144
100
0.0048
0.121
120
0.0040
0.101
150
0.0035
0.088
180
0.0030
0.076
220
0.0025
0.063
240
0.0020
0.050
(a)
CHART 34–1 Grit size numbers and their dimensions in inches and millimeters.
pressure produces fine finishes, and heavy cutting pressure produces rough finishes. The surface finish should match the surface required for the type of piston rings to be used. Typical grit and surface finish standards include the following:
Chrome rings: 180 grit (25 to 35 microinches)
Cast-iron rings: 200 grit (20 to 30 microinches)
Moly rings: 220 grit (18 to 25 microinches)
NOTE: The correct honing oil and coolant are critical to proper operation of the honing equipment and to the quality of the finished cylinders.
CYLINDER HONING PROCEDURE
The procedure includes
(b)
FIGURE 34–31 (a) The surface finish tool is being held against the cylinder wall. (b) The reading indicates the Ra roughness of the cylinder. More work is needed if moly piston rings are to be used. finished cylinder should be within 0.0005 in. (0.013 mm) on both out-of-round and taper measurements. SEE FIGURE 34–31 for an example of cylinder surface finish reading.
the following steps. STEP 1
The hone is placed in the cylinder. Before the drive motor is turned on, the hone is moved up and down in the cylinder to get the feel of the stroke length needed. The end of the hone should just break out of the cylinder bore on each end. The hone must not be pulled from the top of the cylinder while it is rotating. Also, it must not be pushed so low in the cylinder that it hits the main bearing web or crankshaft.
STEP 2
The sizing hone is adjusted to give a solid drag at the lower end of the stroke.
STEP 3
The hone drive motor is turned on and stroking begins immediately. Stroking continues until the sound of the drag is reduced.
STEP 4
The hone drive motor is turned off while it is still stroking. Stroking is stopped as the rotation of the hone stops. After rotation stops, the hone is collapsed and removed from the cylinder.
STEP 5
The cylinder is examined to check the bore size and finish of the wall. If more honing is needed, the cylinder is again coated with honing oil and the cylinder is honed again. The
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CHAMFERING THE CYLINDER BORES
Whenever machining is performed on the block such as boring and decking, the top edge of the cylinder bores have sharp edges. These sharp edges must be removed to allow the piston with rings to be installed. The slight chamfer allows the rings to enter the cylinder easily when the pistons are installed. A tapered rubber cone covered in sanding cloth is used to remove the sharp edges. SEE FIGURE 34–32.
BLOCK PREPARATION FOR ASSEMBLY BLOCK CLEANING
After the cylinders have been honed and before the block is cleaned, use a sandpaper cone to chamfer the top edge of the cylinder. Cleaning the honed cylinder wall is an important part of the honing process. If any grit remains on the cylinder
FIGURE 34–33 High-performance engine builders will often install bronze sleeves in the lifter bores. FIGURE 34–32 Using a tapered sanding cone to remove the sharp edges at the top of the cylinders created when the block was machined. TECH TIP Install Lifter Bore Bushings Lifter bores in a block can be out-of-square with the camshaft, resulting in premature camshaft wear and variations in the valve timing from cylinder to cylinder. To correct for this variation, the lifter bores are bored and reamed oversize using a fixture fastened to the block deck to ensure proper alignment. Bronze lifter bushings are then installed and finish honed to achieve the correct lifter-to-bore clearance. SEE FIGURE 34–33. The lifter bores should be “honed” with a ball-type hone. This should be done even if they are “in-line” and do not need bushings. This is often overlooked by technicians and can lead to lifter problems later on, causing lifters to stick on the bores.
wall, it will rapidly wear the piston rings. This wear will cause premature failure of the reconditioning job. Degreasing and decarbonizing procedures will only remove the honing oil but will not remove the abrasive. The best way to clean the honed cylinders is to scrub the cylinder wall with a brush using a mixture of soap or detergent and water. The block is scrubbed until it is absolutely clean. This can be determined by wiping the cylinder wall with a clean lint free cloth. The cloth will pick up no soil when the cylinder wall is clean. Be sure that the cylinders are dried as soon as possible to avoid rust from forming.
FIGURE 34–34 Notice on this cutaway engine block that some of the head bolt holes do not extend too far into the block and dead end. Debris can accumulate at the bottom of these holes and it must be cleaned out before final assembly.
BLOCK DETAILING Before the engine block can be assembled, a final detailed cleaning should be performed. 1. All oil passages (galleries) should be cleaned by running a long bottle-type brush through all holes in the block. 2. All tapped holes should have the sharp edges at the top of the holes removed (chamfered) and cleaned with the correct size of thread chaser to remove any dirt and burrs. SEE FIGURES 34–34 AND 34–35. 3. Coat the newly cleaned block with fogging oil to prevent rust. Cover the block with a large plastic bag to keep out dirt until it is time to assemble the engine.
FIGURE 34–35 A tread chaser or bottoming tap should be used in all threaded holes before assembling the engine.
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REVIEW QUESTIONS 1. How is Styrofoam used to cast an engine block?
3. What is the difference between deglazing and honing a cylinder?
2. What does “decking the block” mean?
4. What is the best method to use to clean an engine block after honing?
CHAPTER QUIZ 1. The block deck is the ______________. a. Bottom (pan rail) of the block b. Top surface of the block c. Valley surface of a V-type engine d. Area where the engine mounts are attached to the block 2. The surface finish for the cylinder walls usually depends on ______________. a. The type of piston rings to be used b. The type of engine oil that is going to be used in the engine c. The cylinder wall-to-piston clearance d. Both b and c 3. What should be installed and torqued to factory specification before machining a block? a. Front timing chain cover b. Main bearing caps c. Oil pan d. All of the above 4. Cast iron has about how much carbon content? a. Less than 1% c. 3% b. 2% d. 4% or higher 5. Engine blocks can be manufactured using which method(s)? a. Sand cast b. Sand cast or die cast c. Extruded cylinder d. Machined from a solid piece of metal (either cast iron or aluminum)
chapter
35
6. A bedplate is located between the ______________ and the ______________. a. Cylinder bores; water jacket b. Cylinder head; block deck c. Bottom of the block; oil pan d. Block deck; cylinder bore 7. Siamese cylinder bores are ______________. a. Cylinders that do not have a coolant passage between them b. Aluminum cylinders c. Another name for cylinder liners d. Cast-iron cylinders 8. Ultrasonic testing is used to test ______________. a. For cracks in the block b. Surface finish of the cylinder bores c. Cylinder wall thickness d. Both b and c 9. An engine block should be machined in which order? a. Align honing, cylinder boring, block deck machining b. Block decking, align honing, cylinder boring c. Cylinder boring, align honing, block decking d. Align honing, block decking, cylinder boring 10. After the engine block has been machined, it should be cleaned using ______________. a. Soap and water b. SAE 10W-30 oil and a shop cloth c. Sprayed-on brake cleaner to remove the cutting oil d. Sprayed-on WD-40
CRANKSHAFTS, BALANCE SHAFTS, AND BEARINGS
OBJECTIVES: After studying Chapter 35, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “C” (Engine Block Diagnosis and Repair). • Describe the purpose and function of a crankshaft. • Discuss how to measure crankshafts. • Explain how crankshafts are machined and polished. • Discuss the purpose and function of balance shafts. • Discuss engine bearing construction and installation procedures. KEY TERMS: Aluminum 375 • Amplitude 369 • Babbitt 375 • Bank 367 • Bearing crown 374 • Bearing shell 375 • Billet 367 • Case hardening 366 • Conformability 376 • Copper-lead alloy 375 • Corrosion resistance 377 • Counterweights 369 • Crankpins 365 • Crankshaft centerline 365 • Crush 378 • Elastomer 369 • Electroplating 375 • Embedability 377 • Fatigue life 376 • Flying web 369 • Frequency 369 • Full round bearing 379 • Fully counterweighted 369 • Half-shell bearing 376 • Hub 369 • Inertia ring 369 • Nitriding 366 • Overlay 375 • Plain bearing 374 • Precision insert-type bearing shells 376 • Primary vibration 371 • Resonate 369 • Score resistance 377 • Secondary vibration 371 • Sleeve bearing 374 • Splay angle 369 • Split-type (half-shell) bearing 379 • Spread 378 • Spun bearing 378 • Surface finish 366 • Thrust bearing 365 • Tuftriding 366 • Work hardened 376
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FLYWHEEL FLANGE
BALANCING HOLE
FILLETS MAIN BEARING JOURNAL
OIL PASSAGE
REAR MAIN SEAL SURFACE
CONNECTING ROD JOURNAL
COUNTERWEIGHT CRANK SNOUT
OIL PASSAGE
CRANK CHEEKS
FIGURE 35–1 Typical crankshaft with main journals that are supported by main bearings in the block. Rod journals are offset from the crankshaft centerline.
STUD
CRANKSHAFT
BOLT
PURPOSE AND FUNCTION Power from expanding gases in the combustion chamber is delivered to the crankshaft through the piston, piston pin, and connecting rod. The connecting rods and their bearings are attached to a bearing journal on the crank throw. The crank throw is offset from the crankshaft centerline. The distance between the centerline of the connecting rod bearing journal and the centerline of the crankshaft main bearing journal determines the stroke of the engine. The engine stroke is calculated by multiplying the distance between the two centerlines by 2. The combustion force is applied to the crank throw after the crankshaft has moved past top center. This produces the turning effort or torque, which rotates the crankshaft. The crankshaft rotates on the main bearings. These bearings are split in half so that they can be assembled around the crankshaft main bearing journals. The crankshaft includes the following parts.
Main bearing journals
Rod bearing journals
Crankshaft throws
Counterweights
Front snout
Flywheel flange
Keyways
Oil passages
SEE FIGURE 35–1.
MAIN BEARING JOURNALS The crankshaft rotates in the cylinder block supported on main bearings. SEE FIGURE 35–2. The main bearings support the crankshaft and allow it to rotate easily without excessive wear. The number of cylinders usually determines the number of main bearings.
Four-cylinder engines and V-8 engines usually have five main bearings.
Inline 6-cylinder engines usually have seven main bearings.
V-6 engines normally have only four main bearings.
The crankshaft also must be able to absorb loads applied longitudinally (end to end) or thrust loads from the clutch on a manual
REAR CAP
CAP CAP CAP
MAIN BEARING INSERT
CRANKSHAFT
THRUST BEARING INSERT
MAIN BEARING INSERT THRUST BEARING INSERT
CYLINDER BLOCK
FRONT
FIGURE 35–2 The crankshaft rotates on main bearings. Longitudinal (end-to-end) movement is controlled by the thrust bearing. transmission vehicle or the torque converter on a vehicle equipped with an automatic transmission. Thrust loads are forces that push and pull the crankshaft forward and rearward in the engine block. A thrust bearing supports these loads and maintains the front-to-rear position of the crankshaft in the block. SEE FIGURE 35–3. The thrust surface on many engines is usually located at the middle or one of the end main bearings. On most engines, the bearing insert for the main bearing is equipped with thrust bearing flanges that ride against the thrust surface.
ROD BEARING JOURNALS The rod bearing journals, also called crankpins, are offset from the centerline of the crank. Inserttype bearings fit between the big end of the connecting rod and the crankpin of the crankshaft. The crankshaft throw distance that C RAN K SH AF T S, BAL AN C E SH AF T S, AN D BEA RIN GS
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CRANKSHAFT THRUST SURFACE THRUST BEARING
FIGURE 35–3 A ground surface on one of the crankshaft cheeks next to a main bearing supports thrust loads on the crank.
FIGURE 35–5 Wide separation lines of a forged crankshaft.
CENTERLINE OF CYLINDER
and adding carbon to the journals where it causes the outer surface to become harder than the rest of the crankshaft. If the entire crankshaft was hardened, it would become too brittle to absorb the torsional stresses of normal engine operation.
Nitriding, when the crankshaft is heated to about 1,000°F (540°C) in a furnace filled with ammonia gas, and then allowed to cool. The process adds nitrogen (from the ammonia) into the surface of the metal-forming hard nitrides in the surface of the crankshaft to a depth of about 0.007 in. (0.8 mm).
Tuftriding, another variation of this process, involves heating the crankshaft in a molten cyanide salt bath. Tuftriding is a trade name of General Motors.
PISTON
CONNECTING ROD
CRANKPIN CENTERLINE OF CRANKSHAFT MAIN BEARING JOURNAL
CENTERLINE OF CRANKPIN E AG ER E LEV TANC DIS
FIGURE 35–4 The distance from the crankpin centerline to the centerline of the crankshaft determines the stroke, which is the leverage available to turn the crankshaft. measures one-half of the stroke has a direct relationship to the displacement of the engine. Engine stroke is equal to twice the leverage distance or two times the length of the crankshaft throw. SEE FIGURE 35–4.
SURFACE FINISH All crankshaft journals are ground to a very smooth finish. Surface finish is measured in microinches; and the smaller the number, the smoother the surface. The typical specification for main and rod crankshaft journals is between 10 and 20 roughness average (Ra). This very smooth surface finish is achieved by polishing the crank journals after the grinding operation.
CRANKSHAFT CONSTRUCTION FORGED Crankshafts used in high-production automotive engines may be either forged or cast. Forged crankshafts are stronger than the cast crankshaft, but they are more expensive. Forged crankshafts may have a wide separation line. The wide separation line is the result of a grinding process to remove the metal that was extruded from the forging die during the forging process. SEE FIGURE 35–5. Most high-performance forged crankshafts are made from SAE 4340 or a similar type of steel. The crankshaft is formed from a hot steel billet through the use of a series of forging dies. Each die changes the shape of the billet slightly. The crankshaft blank is finally formed with the last die. The blanks are then machined to finish the crankshaft. Forging makes a very dense, tough crankshaft with the metal’s grain structure running parallel to the principal direction of stress. Two methods are used to forge crankshafts.
JOURNAL HARDNESS
To improve wear resistance, some manufacturers harden the crankshaft journals. Methods used to harden the crankshaft journals include:
Case hardening, where only the outer portion of the surface is hardened. Case hardening involves heating the crankshaft
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One method is to forge the crankshaft in place. This is followed by straightening. The forging in place method is primarily used with forged 4- and 6-cylinder crankshafts. A second method is to forge the crankshaft in a single plane. It is then twisted in the main bearing journal to index the throws at the desired angles. Most newer crankshafts are not twisted.
OVERLAP CRANK THROW
MAIN BEARING JOURNAL
CRANKSHAFT OILING HOLES
CONNECTING ROD JOURNAL
CAST MOLD PARTING LINES
FIGURE 35–6 Cast crankshaft showing the bearing journal overlap and a straight, narrow cast mold parting line. The amount of overlap determines the strength of the crankshaft.
CAST CRANKSHAFTS Casting materials and techniques have improved cast crankshaft quality so that cast crankshafts are used in most production automotive engines. Automotive crankshafts may be cast in steel, nodular iron, or malleable iron. Advantages of a cast crankshaft are as follows:
FIGURE 35–7 A billet crankshaft showing how it is machined from a large round roll of steel, usually 4340 steel, at the right and the finished crankshaft on the left.
Crankshaft material and machining costs are less than they are with forging. The reason is that the crankshaft can be made close to the required shape and size, including all complicated counterweights. The only machining required on a carefully designed cast crankshaft is the grinding of bearing journal surfaces and the finishing of front and rear drive ends.
Metal grain structure in the cast crankshaft is uniform and random throughout; therefore, the shaft is able to handle loads from all directions.
Counterweights on cast crankshafts are slightly larger than counterweights on a forged crankshaft, because the cast shaft metal is less dense and therefore somewhat lighter.
The narrow mold parting surface lines can be seen on the cast crankshaft in FIGURE 35–6.
BILLET CRANKSHAFTS
A billet crankshaft is machined from a solid piece of forged steel called a billet. This solid piece of steel, usually SAE 4340, is then machined through several operations to create a finished crankshaft. The advantages of a billet crankshaft include:
PURPOSE AND FUNCTION The crankshaft is drilled to allow oil from the main bearing oil groove to be directed to the connecting rod bearings. SEE FIGURE 35–8. The oil on the bearings forms a hydrodynamic oil film to support bearing loads. Some of the oil may be sprayed out through a spit or bleed hole in the connecting rod. The rest of the oil leaks from the edges of the bearing. It is thrown from the bearing against the inside surfaces of the engine. Some of the oil that is thrown from the crankshaft bearings will land on the camshaft to lubricate the lobes. A part of the throw-off, oil splashes on the cylinder wall to lubricate the piston and rings. Stress tends to concentrate at oil holes drilled through the crankshaft journals. These holes are usually located where the crankshaft loads and stresses are the lowest. The edges of the oil holes are carefully chamfered to relieve as much stress concentration as possible. Chamfered oil holes are shown in FIGURE 35–9.
ENGINE CRANKSHAFT TYPES V-8 ENGINE ARRANGEMENT
The V-8 engine has four inline cylinders in each of the two blocks that are placed at a 90-degree angle to each other. Each group of four inline cylinders is called a bank. The crankshaft for the V-8 engine has four throws. The connecting rods from two cylinders are connected to each throw, one from each bank. This arrangement results in a condition of being only minimally unbalanced. The V-8 engine crankshaft has two planes, so there is one throw every 90 degrees. A plane is a flat surface that cuts through the part. These planes could be seen if the crankshaft were cut lengthwise through the center of the main bearing and crankpin journals. Looking at the front of the crankshaft:
The first throw is at 360 degrees (up).
The second throw is at 90 degrees (to the right).
Uniform grain structure created by the forging process
The third throw is at 270 degrees (to the left).
Stiff, strong, and very durable
The fourth throw is at 180 degrees (down).
The disadvantage is the high cost. Billet crankshafts tend to be very expensive because of the large amount of material removal during the machining process and the high material cost and the additional heat treatment required. SEE FIGURE 35–7.
In operation with this arrangement, one piston reaches top center at each 90 degrees of crankshaft rotation so that the engine operates smoothly with even firing at each 90 degrees of crankshaft rotation.
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FIGURE 35–10 A cross-drilled crankshaft is used on some production engines and is a common racing modification. FIGURE 35–8 Crankshaft sawed in half, showing drilled oil passages between the main and rod bearing journals.
?
FREQUENTLY ASKED QUESTION
What Does a “Cross-Drilled Crankshaft” Mean? A cross-drilled crankshaft means that there are two instead of only one oil hole leading from the main bearing journal to the rod bearing journal. Oil is supplied to the main bearing journals through oil galleries in the block. A cross-drilled crankshaft has two outlet holes for oil to reach the drilled passage that supplies oil to the rod journal. SEE FIGURE 35–10.
CHAMFERED OIL HOLE
REAL WORLD FIX The Mysterious Engine Vibration FILLET
FLANGE
FIGURE 35–9 Typical chamfered hole in a crankshaft bearing journal.
FOUR-CYLINDER ENGINE CRANKSHAFTS
The crankshaft used on 4-cylinder inline engines has four throws on a single plane. There is usually a main bearing journal between each throw, making it a five main bearing crankshaft. Pistons also move as pairs in this engine.
Pistons in cylinders 1 and 4 move together, and pistons 2 and 3 move together.
Each piston in a pair is 360 degrees out-of-phase with the other piston in the 720-degree four-stroke cycle. With this arrangement, the 4-cylinder inline engine fires one cylinder at each 180 degrees of crankshaft rotation.
A Buick 3.8 liter V-6 engine vibrated the whole car after a new short block had been installed. The technician who had installed the replacement engine did all of the following: 1. Checked the spark plugs 2. Checked the spark plug wires 3. Disconnected the torque converter from the flex plate (drive plate) to eliminate the possibility of a torque converter or automatic transmission pump problem 4. Removed all accessory drive belts one at a time Yet the vibration still existed. Another technician checked the engine mounts and found that the left (driver’s side) engine mount was out of location, ripped, and cocked. The transmission mount was also defective. After the technician replaced both mounts and made certain that all mounts were properly set, the vibration was eliminated. The design and location of the engine mounts are critical to the elimination of vibration, especially on 90-degree V-6 engines.
A 4-cylinder opposed (flat) engine and a 90-degree V-4 engine have crankshafts that look like that of the 4-cylinder inline engine.
yet the vibration was satisfactorily dampened and isolated on both the Audi and Acura 5-cylinder engines.
FIVE-CYLINDER ENGINE CRANKSHAFTS The inline 5-cylinder engine has a five-throw crankshaft with one throw at each 72 degrees. Six main bearings are used on this crankshaft. The piston in one cylinder reaches top center at each 144 degrees of crankshaft rotation. Dynamic balancing has been one of the major problems with this engine design,
THREE-CYLINDER ENGINE CRANKSHAFTS A 3-cylinder engine uses a 120-degree three-throw crankshaft with four main bearings. This engine requires a balancing shaft that turns at crankshaft speed, but in the opposite direction, to reduce the vibration to an acceptable level.
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SPLAYED CRANKPIN
FIGURE 35–12 A fully counterweighted 4-cylinder crankshaft.
?
FREQUENTLY ASKED QUESTION
What Is an Offset Crankshaft? To reduce side loads, some vehicle manufacturers offset the crankshaft from center. For example, if an engine rotates clockwise as viewed from the front, the crankshaft may be offset to the left to reduce the angle of the connecting rod during the power stroke. SEE FIGURE 35–13. The offset usually varies from 1/16 to 1/2 in., depending on make and model. Many inline 4-cylinder engines used in hybrid electric vehicles use an offset crankshaft.
FIGURE 35–11 A splayed crankshaft design is used to create an even-firing 90-degree V-6.
INLINE SIX-CYLINDER ENGINE CRANKSHAFT
Inline six cylinder engine crankshafts ride on four or seven main bearings and use six crank throws in three planes 120 degrees apart. An inline six cylinder is in perfect primary and secondary balance.
90-DEGREE V-6 ENGINE CRANKSHAFTS The crank throws for an even-firing V-6 engine are split, making separate crankpins for each cylinder. The split throw can be seen in FIGURE 35–11. This angle between the crankpins on the crankshaft throws is called a splay angle. A flange was left between the split crankpin journals. This provides a continuous fillet or edge for machining and grinding operations. It also provides a normal flange for the rod and bearing. This flange between the splayed crankpin journals is sometimes called a flying web. 60-DEGREE V-6 ENGINE CRANKSHAFTS The 60-degree V-6 engine is similar to the even-firing 90-degree V-6 engine. The adjacent pairs of crankpins on the crankshaft used in the 60-degree V-6 engine have a splay angle of 60 degrees. The crankshaft of the 60-degree V-6 engine also uses four main bearings.
COUNTERWEIGHTS PURPOSE AND FUNCTION
Crankshafts are balanced by counterweights, which are cast, forged, or machined as part of the crankshaft. A crankshaft that has counterweights on both sides of each connecting rod journal is called fully counterweighted. SEE FIGURE 35–12. A fully counterweighted crankshaft is the smoothest running and most durable design, but it is also the heaviest and most expensive to manufacture. Most vehicle manufacturers do not use fully
counterweighted crankshafts in an effort to lighten the rotating mass of the engine. An engine with a light crankshaft allows the engine to accelerate quicker. Even crankshafts that are not fully counterweighted are still balanced.
VIBRATION DAMAGE
Each time combustion occurs, the force deflects the crankshaft as it transfers torque to the output shaft. This deflection occurs in two ways, to bend the shaft sideways and to twist the shaft in torsion. The crankshaft must be rigid enough to keep the deflection forces to a minimum. Crankshaft deflections are directly related to the operating roughness of an engine. When back-and-forth deflections occur at the same vibration frequency (number of vibrations per second) as that of another engine part, the parts will vibrate together. When this happens, the parts are said to resonate. These vibrations may become great enough to reach the audible level, producing a thumping sound. If this type of vibration continues, the crankshaft may fail. SEE FIGURE 35–14. Harmful crankshaft twisting vibrations are dampened with a torsional vibration damper. It is also called a harmonic balancer. This damper or balancer usually consists of a cast-iron inertia ring mounted to a cast-iron hub with an elastomer sleeve.
HINT: Push on the rubber (elastomer sleeve) of the vibration damper with your fingers or a pencil. If the rubber does not spring back, replace the damper. Elastomers are actually synthetic, rubberlike materials. The inertia ring size is selected to control the amplitude of the crankshaft vibrations for each specific engine model. SEE FIGURE 35–15.
EXTERNALLY AND INTERNALLY BALANCED ENGINES DEFINITION
Most crankshaft balancing is done during manufacture. Holes are drilled in the counterweight to lighten and improve balance. Sometimes these holes are drilled after the crankshaft is installed in the engine. Some manufacturers are able to control casting
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CENTERLINE OF CYLINDER
CENTERLINE OF CYLINDER
PISTON
PISTON
CONNECTING ROD
CONNECTING ROD CRANKSHAFT OFFSET REDUCES ANGLE
CENTERLINE OF CRANKSHAFT MAIN BEARING
ANGLE A 91°
MAIN JOURNAL
ANGLE B 97°
CENTERLINE OF CRANKSHAFT MAIN BEARING
CONNECTING ROD JOURNAL
MAIN JOURNAL
CONNECTING ROD JOURNAL
OFFSET
FIGURE 35–13 The crank throw is halfway down on the power stroke. The piston on the left without an offset crankshaft has a sharper angle than the engine on the right with an offset crankshaft. COUNTER FORCE CREATED BY OUTER RING MASS
ELASTOMETRIC (RUBBER) RING
FIGURE 35–14 A crankshaft broken as a result of using the wrong torsional vibration damper.
TECH TIP High Engine Speeds Require High-Performance Parts Do not go racing with stock parts. A stock harmonic balancer can come apart and the resulting vibration can break the crankshaft if the engine is used for racing. Check the Internet or race part suppliers for the recommended balancer to use. SEE FIGURE 35–16.
quality so closely that counterweight machining for balancing is not necessary. Engine manufacturers balance an engine in one of two ways.
Externally balanced. Weight is added to the harmonic balancer (vibration damper) and flywheel or the flexplate.
Internally balanced. All rotating parts of the engine are individually balanced, including the harmonic balancer and flywheel (flexplate).
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CYLINDER FIRING PULSES
FIGURE 35–15 The hub of the harmonic balancer is attached to the front of the crankshaft. The elastomer (rubber) between the inertia ring and the center hub allows the absorption of crankshaft firing impulses. For example, the 350-cubic-inch Chevrolet V-8 is internally balanced, whereas the 400-cubic-inch Chevrolet V-8 uses an externally balanced crankshaft. The harmonic balancer used on an externally balanced engine has additional weight.
ENGINE BALANCE PRIMARY AND SECONDARY BALANCE Anything that rotates will vibrate. This means that an engine will vibrate during
PRIMARY
SECONDARY
FIGURE 35–18 Primary and secondary vibrations in relation to piston position.
FIGURE 35–16 A General Motors high-performance balancer used on a race engine.
BALANCE SHAFT ROTATING IN THE SAME DIRECTION AS THE CRANKSHAFT
FIGURE 35–17 In a 4-cylinder engine, the two outside pistons move upward at the same time as the inner pistons move downward, which reduces primary unbalance.
OIL PUMP GEARS REVERSE THE DIRECTION OF ROTATION
operation, although engine designers attempt to reduce the vibration as much as possible.
Primary balance. When pistons move up and down in the cylinders they create a primary vibration, which is a strong low-frequency vibration. A counterweight on the crankshaft opposite the piston/ rod assembly helps reduce this vibration. An inline 4-cylinder engine has very little primary vibration, because as two pistons are traveling upward in the cylinders, two are moving downward at the same time, effectively canceling out primary unbalances. SEE FIGURE 35–17. Secondary balance. Four-cylinder engines, however, suffer from a vibration at twice engine speed. This is called a secondary vibration, which is a weak high-frequency vibration caused by a slight difference in the inertia of the pistons at top dead center compared to bottom dead center. This vibration is most noticeable at high engine speeds, especially if the engine size is greater than 2 liters. The larger the displacement of the engine, the larger the bore and the heavier the pistons contribute to the buzzing-type secondary vibration. SEE FIGURE 35–18.
BALANCE SHAFTS
FIGURE 35–19 Two counterrotating balance shafts used to counterbalance the vibrations of a 4-cylinder engine.
engine. Weights on the ends of the balance shaft move in a direction opposite to the direction of the end piston. When the piston goes up, the weight goes down, and when the piston goes down, the weight goes up. This reduces the end-to-end rocking action on the 3-cylinder inline engine. Another type of balance shaft system is designed to counterbalance vibrations on a four-stroke, 4-cylinder engine. Two shafts are used, and they turn at twice the engine speed. In most applications, both shafts rotate in the same direction and are driven by a chain or gear off the crankshaft. Counterweights on the balance shafts are positioned to oppose the natural rolling action of the engine, as well as the secondary vibrations caused by the piston and rod movements. SEE FIGURE 35–19.
BALANCE SHAFT APPLICATIONS
Balance shafts are commonly found on the larger displacement (over 2 liter) 4-cylinder automotive engines.
Most 4-cylinder engines larger than 2.2 liters use balance shafts. These are often located underneath the crankshaft. SEE FIGURE 35–20.
Since the late 1980s, both Ford and General Motors added a balance shaft to many of their V-6 engines. These 90-degree V-6 engines use a split crank journal to create an even-firing
PURPOSE AND FUNCTION
Some engines use balance shafts to dampen normal engine vibrations. Dampening is reducing the vibration to an acceptable level. A balance shaft that is turning at crankshaft speed, but in the opposite direction, is used on a 3-cylinder inline
DRIVE CHAIN
BALANCE SHAFT ROTATING IN THE OPPOSITE DIRECTION TO THE CRANKSHAFT
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arrangement, but these engines suffer from forces that cause the engine to rock back and forth. This motion is called a rocking couple and is dampened by the use of a balance shaft. SEE FIGURE 35–21. The addition of balance shafts makes a big improvement in the smoothness of the engine. In V-6 engines, the improvement is most evident during idling and low-speed operation, whereas in the 4-cylinder engines, balance shafts are especially helpful at higher engine speeds. The V-6 engines that use a 60-degree design do not create a rocking couple and, therefore, do not need a balance shaft.
CHAIN TENSIONER
REAR OF CRANKSHAFT
BALANCE SHAFTS
CRANKSHAFT SERVICE CRANKSHAFT VISUAL INSPECTION
Crankshaft damage
includes:
Worn journals
Scored bearing journals
Bends or warpage
Cracks
Thread damage (flywheel flange or front snout)
Worn front or rear seal surfaces
Damaged shafts must be reconditioned or replaced. The crankshaft is one of the most highly stressed engine parts. The stress on the crankshaft increases by four times every time the engine speed doubles. Any sign of a crack is a cause to reject the crankshaft. Most cracks can be seen during a close visual inspection. Crankshafts should also be checked with Magnaflux, which will highlight tiny cracks that would lead to failure. Bearing journal scoring is a common crankshaft defect. Scoring appears as scratches around the bearing journal surface. Generally, there is more scoring near the center of the bearing journal, as shown in FIGURE 35–22. Crankshaft journals should be inspected for nicks, pits, or corrosion. Roughness and slight bends in journals can be corrected by grinding the journals. HINT: If your fingernail catches on a groove when rubbed across a bearing journal, the journal is too rough to reuse and must be reground. Another test is to rub a copper penny across the journal. If any copper remains on the crankshaft, it must be reground.
FIGURE 35–20 This General Motors 4-cylinder engine uses two balance shafts driven by a chain at the rear of the crankshaft. ROLLER BEARING
BALL BEARING
GEAR DRIVEN BALANCE SHAFT
FIGURE 35–21 Many 90-degree V-6 engines use a balance shaft to reduce vibrations and effectively cancel a rocking motion (rocking couple) that causes the engine to rock front to back.
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CHECK FOR OUT-OF-ROUNDNESS AT EACH END OF JOURNAL
B
A
D
C
A VS. B = VERTICAL TAPER C VS. D = HORIZONTAL TAPER
FIGURE 35–22 Scored connecting rod bearing journal.
A VS. C = OUT OF ROUND B VS. D = OUT OF ROUND
FIGURE 35–24 Check each journal for taper and out-of-round.
FIGURE 35–23 All crankshaft journals should be measured for diameter as well as taper and out-of-round.
MEASURING THE CRANKSHAFT Crankshafts should be carefully measured to determine the following:
Size of main and rod bearing journals compared to factory specifications
Each journal checked for out-of-round condition
Each journal checked for taper
FIGURE 35–25 The rounded fillet area of the crankshaft is formed by the corners of the grinding stone.
SEE FIGURES 35–23 AND 35–24. STEP 5
CRANKSHAFT GRINDING
Crankshaft journals that have excessive scoring, out-of-round, or taper should be reground. The typical procedure includes the following steps. STEP 1
Crankshafts may require straightening before grinding.
STEP 2
Both crankshaft ends are placed in rotating heads on one style of crankshaft grinder.
STEP 3
The main bearing journals are ground on the centerline of the crankshaft.
STEP 4
The crankshaft is then offset in the two rotating heads just enough to make the crankshaft main bearing journal centerline rotate around the centerline of the crankpin. The crankshaft will then be rotating around the crankpin centerline. The journal on the crankpin is reground in this position.
The crankshaft must be repositioned for each different crankpin center.
In another type of crankshaft grinder, the crankshaft always turns on the main bearing centerline. The grinding head is programmed to move in and out as the crankshaft turns to grind the crankpin bearing journals. Crankshafts are usually ground to the following undersize.
0.010 in.
0.020 in.
0.030 in.
The finished journal should be accurately ground to size with a smooth surface finish. The radius of the fillet area on the sides of the journal should also be the same as the original. SEE FIGURE 35–25.
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FIGURE 35–26 An excessively worn crankshaft can be restored to useful service by welding the journals, and then machining them back to the original size.
FIGURE 35–28 Crankshafts should be stored vertically to prevent possible damage or warpage. This clever bench-mounted tray for crankshafts not only provides a safe place to store crankshafts but is also out of the way and cannot be accidentally tipped. cover the journal to prevent damage to the rest of it. Stress relief procedures are usually performed after the grinding and polishing of the crankshaft.
STORING CRANKSHAFTS All crankshafts should be coated with oil to keep them from rusting, and stored vertically until time for engine assembly. All crankshafts should be placed on the floor vertically to help prevent warping due to gravity. SEE FIGURE 35–28.
ENGINE BEARINGS
FIGURE 35–27 All crankshafts should be polished after grinding. Both the crankshaft and the polishing cloth are being revolved.
CRANKSHAFT POLISHING The journal is polished after grinding using a 320-grit polishing cloth and oil to remove the fine metal “fuzz” remaining on the journal. This fuzz feels smooth when the shaft turns in its direction. As the shaft turns in the opposite direction, the fuzz feels like a fine milling cutter. Polishing removes this fuzz. The crankshaft is rotated in its normal direction of rotation so that the polishing cloth can remove the fuzz. This leaves a smooth shaft with the proper surface finish. Most crankshaft grinders grind in the direction opposite of rotation and then polish in the same direction as rotation. SEE FIGURE 35–26. The crankshaft oil passages should be cleaned and the journals tagged with the undersize dimensions. WELDING A CRANKSHAFT
Sometimes it is desirable to salvage a crankshaft by building up a bearing journal and then grinding it to the original journal size. This is usually done by either electric arc welding or a metal spray. SEE FIGURE 35–27.
STRESS RELIEVING THE CRANKSHAFT
The greatest area of stress on a crankshaft is the fillet area. Stress relief is achieved by shot peening the fillet area of the journals with #320 steel shot. This strengthens the fillet area and helps to prevent the development of cracks in this area. Gray duct tape is commonly used to
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INTRODUCTION Engine bearings are the main supports for the major moving parts of any engine. Engine bearings are important for the following reasons. 1. The clearance between the bearings and the crankshaft is a major factor in maintaining the proper oil pressure throughout the entire engine. Most engines are designed to provide the maximum protection and lubrication to the engine bearings above all else. 2. Engine durability relies on bearing life. Bearing failure usually results in immediate engine failure. 3. Engine bearings are designed to support the operating loads of the engine and, with the lubricant, provide minimum friction. This must be achieved at all designed engine speeds. The bearings must be able to operate for long periods of time, even when small foreign particles are in the lubricant.
TYPES OF BEARINGS
Most engine bearings are one of two
types.
Plain bearing
Sleeve bearing
SEE FIGURE 35–29. Most bearing halves, or shells, do not have uniform thickness. The wall thickness of most bearings is largest in the center, called the bearing crown. The bearing thickness then tapers to a thinner measurement at each parting line. SEE FIGURE 35–30. The tapered wall keeps bearing clearances close at the top and bottom of the bearing, which are the more loaded areas and
allow more oil flow at the sides of the bearing. Both need a constant flow of lubricating oil. In automotive engines, the lubricating system supplies oil to each bearing continuously when the engine runs. Bearings and journals only wear when the parts come in contact with each other or when foreign particles are present. Oil enters the bearing through the oil holes and grooves. It spreads into a smooth wedge-shaped oil film that supports the bearing load.
BEARING MATERIALS
needed for the shaft load. The bearing material meets the rest of the bearing operating requirements.
Babbitt. Babbitt is the oldest automotive bearing material. Isaac Babbitt (1799–1862) first formulated this material in 1839. An excellent bearing material, it was originally made from a combination of lead, tin, and antimony. Lead and tin are alloyed with small quantities of copper and antimony to give it the required strength. Babbitt is still used in applications in which material is required for soft shafts running under moderate loads and speeds. It will work with occasional borderline lubrication and oil starvation without failure.
Trimetal. Copper-lead alloy is a stronger and more expensive bearing material than babbitt. It is used for intermediate- and high-speed applications. Tin, in small quantities, is often alloyed with the copper-lead bearings. This bearing material is most easily damaged by corrosion from acid accumulation in the engine oil. Corrosion results in bearing journal wear as the bearing is eroded by the acids. Many of the copper-lead bearings have an overlay, or third layer, of metal. This overlay is usually of babbitt. Babbitt-overlayed bearings have high fatigue strength, good conformity, good embedability, and good corrosion resistance. The overplated bearing is a premium bearing. It is also the most expensive because the overplating layer, from 0.0005 to 0.001 in. (0.0125 to 0.025 mm) thick, is put on the bearing with an electroplating process. The layers of bearing material on a bearing shell are illustrated in FIGURE 35–31.
Aluminum. Aluminum was the last of the three materials to be used for automotive bearings. Automotive bearing aluminum has small quantities of tin and silicone alloyed with it. This makes a stronger but more expensive bearing than either babbitt or copper-lead alloy. Most of its bearing characteristics are equal to or better than those of babbitt and copper lead. Aluminum bearings are well suited to high-speed, highload conditions and do not contain lead, which is a benefit to the environment both at the manufacturing plant and for the technician who may be exposed to the bearings.
Three materials are used for automo-
bile engine bearings.
Babbitt
Copper-lead alloy
Aluminum
A layer of the bearing materials that is 0.01 to 0.02 in. (0.25 to 0.5 mm) thick is applied over a low carbon steel backing. An engine bearing is called a bearing shell, which is a steel backing with a surface coating of bearing material. The steel provides support
PARTING FACES
PARTING FACES
FIGURE 35–29 The two halves of a plain bearing meet at the parting faces.
CENTERLINE WALL
ECENTRICITY = AMOUNT OF CHANGE IN WALL AT THIS POINT, FROM CENTERLINE BEARING HALFSHELLS
1/4"
3/8" PARTING LINE
PARTING LINE RELIEF
FIGURE 35–30 Bearing wall thickness is not the same from the center to the parting line. This is called eccentricity and is used to help create an oil wedge between the journal and the bearing.
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1
1
2
2
3
BABBITT (3)
COPPER-LEAD (2) ALLOY
FIGURE 35–33 Bearings are often marked with an undersize dimension. This bearing is used on a crankshaft with a ground journal that is 0.020 in. smaller in diameter than the stock size.
Before purchasing bearings, be sure to use a micrometer to measure all main and connecting rod journals. Replacement bearings are also available in 0.001, 0.002, and 0.003 in., to allow the technician to achieve the proper bearing clearance without needing to machine the crankshaft.
STEEL (1)
FIGURE 35–31 Typical two- and three-layer engine bearing inserts showing the relative thickness of the various materials.
(b) (a)
BEARING LOADS
The forces on the engine bearings vary with engine speed and load. On the intake stroke, the inertia force is opposed by the force of drawing in the air-fuel mixture. On the compression and power strokes, there is also an opposing force on the rod bearings. On the exhaust stroke, however, there is no opposing force to counteract the inertia force of the piston coming to a stop at TDC. The result is a higher force load on the bottom rod bearing due to inertia at TDC of the exhaust stroke. These forces tend to stretch the big end of the rod in the direction of rod movement. 1. As engine speed (RPM) increases, rod bearing loads decrease because of the balancing of inertia and opposing loads. 2. As engine speed (RPM) increases, the main bearing loads increase. NOTE: This helps explain why engine blocks with fourbolt main bearing supports are only needed for highengine speed stability.
(c)
(d)
FIGURE 35–32 Typical bearing shell types found in modern engines: (a) half-shell thrust bearing, (b) upper main bearing insert, (c) lower main bearing insert, (d) full round-type camshaft bearing.
BEARING MANUFACTURING Modern automotive engines use precision insert-type bearing shells, sometimes called halfshell bearings. The bearing is manufactured to very close tolerance so that it will fit correctly in each application. The bearing, therefore, must be made from precisely the correct materials under closely controlled manufacturing conditions. FIGURE 35–32 shows the typical bearing types found in most engines. BEARING SIZES Bearings are usually available in standard (std.) size, and in measurements 0.010, 0.020, and 0.030 in. undersize. SEE FIGURE 35–33. Even though the bearing itself is thicker for use on a machined crankshaft, the bearing is referred to as undersize because the crankshaft journals are undersize. Factory bearings may be available in 0.0005 or 0.001 in. undersize for precision fitting of a production crankshaft.
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3. Because the loads on bearings vary and affect both rod and main bearings, it is generally recommended that all engine bearings be replaced at one time.
BEARING FATIGUE
Bearings tend to flex or bend slightly under changing loads. This is especially noticeable in reciprocating engine bearings. Bearing metals, like other metals, tend to fatigue and break after being flexed or bent a number of times. Flexing starts fatigue, which shows up as fine cracks in the bearing surface because the bearing material became work hardened. These cracks gradually deepen almost to the bond between the bearing metal and the backing metal. The cracks then cross over and intersect with each other. In time, this will allow a piece of bearing material to fall out. The length of time before fatigue will cause failure is called the fatigue life of the bearing. SEE FIGURE 35–34.
BEARING CONFORMABILITY
The ability of bearing materials to creep or flow slightly to match shaft variations is called conformability. The bearing conforms to the shaft during the engine break-in period. In modern automobile engines, there is little need for bearing conformability or break-in, because automatic processing has achieved machining tolerances that keep the shaft very close to the designed size.
FATIGUE CRACKS APPEAR IN SURFACE
BABBITT BOND LINE STEEL BACK
FATIGUE CRACKS WIDEN AND DEEPEN
CRACKS TURN AND RUN PARALLEL TO THE BOND LINE, EVENTUALLY CAUSING FLAKING
FIGURE 35–34 Work hardened bearing material becomes brittle and cracks, leading to bearing failure. BEARING SHAFT
EMBEDDED FOREIGN PARTICLES
FIGURE 35–35 Bearing material covers foreign material (such as dirt) as it embeds into the bearing.
Bearings have a characteristic called score resistance. It prevents the bearing materials from seizing to the shaft during oil film breakdown. By-products of combustion form acids in the oil. The bearings’ ability to resist attack from these acids is called corrosion resistance. Corrosion can occur over the entire surface of the bearing. This will remove material and increase the oil clearance. It can also leach or eat into the bearing material, dissolving some of the bearing material alloys. Either type of corrosion will reduce bearing life.
BEARING EMBEDABILITY
Engine manufacturers have designed engines to produce minimum crankcase deposits. This has been done by providing them with oil filters, air filters, and closed crankcase ventilation systems that minimize contaminants. Still, some foreign particles get into the bearings. The bearings must be capable of embedding these particles into the bearing surface so that they will not score the shaft. To fully embed the particle, the bearing material gradually works across the particle, completely covering it. The bearing property that allows it to do this is called embedability. SEE FIGURE 35–35.
BEARING DAMAGE RESISTANCE Under some operating conditions, the bearing will be temporarily overloaded. This will cause the oil film to break down and allow the shaft metal to come in contact with the bearing metal. As the rotating crankshaft contacts the bearing high spots, the spots become hot from friction. The friction causes localized hot spots in the bearing material that seize or weld to the crankshaft. The crankshaft then breaks off particles of the bearing material and pulls the particles around with it, scratching or scoring the bearing surface.
BEARING CLEARANCE IMPORTANCE OF PROPER CLEARANCE The bearingto-journal clearance may be from 0.0005 to 0.0025 in. (0.025 to 0.06 mm), depending on the engine. Doubling the journal clearance will allow more than four times more oil to flow from the edges of the bearing. The oil clearance must be large enough to allow an oil film to build up, but small enough to prevent excess oil leakage, which would cause loss of oil pressure. A large amount of oil leakage at one of the bearings would starve other bearings farther along in the oil system. This would result in the failure of the oil-starved bearings. CHECKING BEARING CLEARANCE
Bearing oil clearance
can be checked in the following ways. 1. Using Plastigage® between the crankshaft journal and the bearing. The thin plasticlike strip material will deform depending on the clearance.
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BEARING LOOSE IN HOUSING BORE
CRUSH RELIEF
SPREAD
BEARING TIGHT IN HOUSING BORE
AMOUNT OF CRUSH
CRUSH
FIGURE 35–37 Bearings are thinner at the parting line faces to provide crush relief.
FIGURE 35–36 Bearing spread and crush.
2. Measuring the crankshaft journal diameter and the inside diameter of the bearing as it is installed and subtracting the two measurements. The difference is the bearing clearance.
BEARING SPREAD AND CRUSH
The bearing design also includes bearing spread and crush. SEE FIGURE 35–36.
Bearing spread. The bearing shell has a slightly larger arc than the bearing housing. This difference, called bearing spread, makes the shell 0.005 to 0.02 in. (0.125 to 0.5 mm) wider than the housing bore. Spread holds the bearing shell in the housing while the engine is being assembled.
Bearing crush. When the bearing is installed, each end of the bearing shell is slightly above the parting surface. When the bearing cap is tightened, the ends of the two bearing shells touch and are forced together. This force is called bearing crush. Crush holds the bearing in place and keeps the bearing from turning when the engine runs. Crush must exert a force of at least 12,000 PSI (82,740 kPa) at 250°F (121°C) to hold the bearing securely in place. A stress of 40,000 PSI (275,790 kPa) is considered maximum to avoid damaging the bearing or housing. SEE FIGURE 35–37. Bearing shells that do not have enough crush may rotate with the shaft. The result is called a spun bearing. SEE FIGURE 35–38.
FIGURE 35–38 Spun bearing. The lower cap bearing has rotated under the upper rod bearing.
LOCATING TANG
SLOT
BEARING
Bearing tang. A tang or lip helps locate the bearing shell in the housing. When the bearing clearance and “crush” have been worn or destroyed, the bearing can “spin,” thus creating catastrophic failure. The tang often helps prevent this from occurring. SEE FIGURE 35–39.
Many newer engines do not use a tang on the bearing. Always check service information for the exact bearings and procedures to use for the engine being serviced. Replacement bearings should be of a quality as good as or better than that of the original bearings. The replacement bearings must also have the same oil holes and grooves.
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BEARING SADDLE
FIGURE 35–39 The tang and slot help index the bearing in the bore.
CAMSHAFT BORE
ANNULAR GROOVE
OIL HOLE
CAMSHAFT BEARINGS
FRONT
FIGURE 35–40 Many bearings are manufactured with a groove down the middle to improve the oil flow around the main journal. TECH TIP
FIGURE 35–41 Cam-in-block engines support the camshaft with sleeve-type bearings.
Count Your Blessings and Your Pan Bolts! Replacing cam bearings can be relatively straightforward or can involve keeping count of the number of oil pan bolts. For example, Buick-built V-6 engines use different cam bearings depending on the number of bolts used to hold the oil pan to the block.
OIL HOLE TO ROCKER ARM
• Fourteen bolts in the oil pan. The front bearing is special, but the rest of the bearings are the same. • Twenty bolts in the oil pan. Bearings 1 and 4 use two oil feed holes. Bearings 2 and 3 use single oil feed holes.
OIL HOLE TO ROCKER ARM
CAMSHAFT
CAMSHAFT BEARINGS
CAUTION: Some bearings may have oil holes in the top shell only. If these are installed incorrectly, no oil will flow to the connecting or main rods, resulting in instant engine failure. To help the oil spread across the entire bearing, some bearings use an oil groove. SEE FIGURE 35–40.
OIL INLET
Modified engines have more demanding bearing requirements and therefore usually require a higher quality bearing to provide satisfactory service.
CAMSHAFT BEARINGS TYPES OF CAMSHAFT BEARINGS
The camshaft in pushrod engines rotates in sleeve bearings that are pressed into bearing bores within the engine block. Overhead camshaft bearings may be one of two sleeve-type bushings, depending on the design of the bearing supports.
Full round bearings
Split-type (half-shell) bearings
The split-type bearing has direct contact with aluminum saddles integral with the head depending on the design of the bearing supports. The integral aluminum head bearing design often requires the replacement of the entire cylinder head in the event of bearing failure from lack of lubrication. In pushrod engines, the cam bearings are installed in the block. SEE FIGURE 35–41.
CAMSHAFT BEARING INSTALLATION
The best rule of thumb to follow is to replace the cam bearings whenever the main
FIGURE 35–42 Camshaft bearings must be installed correctly so that oil passages are not blocked.
bearings are replaced. The replacement cam bearings must have the correct outside diameter to fit snugly in the cam bearing bores of the block. They must have the correct oil holes and be positioned correctly. SEE FIGURE 35–42. Cam bearings must also have the proper inside diameter to fit the camshaft bearing journals. Details regarding cam bearings include the following:
In many engines, each cam bearing is a different size. The largest is in the front and the smallest is in the rear.
The cam bearing journal size must be checked and each bearing identified before assembly is begun.
The location of each new cam bearing can be marked on the outside of the bearing with a felt-tip marker to help avoid mixing up bearings. Marking in this way will not affect the bearing size or damage the bearing in any way.
Many vehicle manufacturers specify that the cam bearings should be installed “dry” (not oiled) to prevent the cam bearing from moving (spinning) after installation. If the cam bearing
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were oiled, the rotation of the camshaft could cause the cam bearing to rotate and block oil holes that lubricate the camshaft.
Many aluminum cylinder heads have “integral” cam bearings that are not replaceable. The entire cylinder head may need to be replaced if a lubrication problem occurs to the cam bearings, because the entire cylinder head may need to be replaced.
Camshaft bearings used on overhead camshaft engines may be either full round or split depending on the engine design. SEE FIGURE 35–43.
Always follow the installation tool instructions when installing cam bearings.
BEARING CAP
CAMSHAFT BEARING
FIGURE 35–43 Some overhead camshaft engines use split bearing inserts.
REVIEW QUESTIONS 1. How many degrees of crankshaft rotation are there between cylinder firings on an inline 4-cylinder engine, an inline 6-cylinder engine, and a V-8 engine?
2. List the types of engine bearing materials. 3. Describe bearing crush and bearing spread.
CHAPTER QUIZ 1. A forged crankshaft has a ______________. a. Wide parting line b. Thin parting line c. Parting line in one plane d. Both b and c
6. If any crankshaft is ground, it must also be ______________. a. Shot peened b. Chrome plated c. Polished d. Externally balanced
2. A typical V-8 engine crankshaft has ______________ main bearings. a. Three b. Four c. Five d. Seven
7. If bearing-to-journal clearance is doubled, how much oil will flow? a. One-half as much b. The same amount if the pressure is kept constant c. Double the amount d. Four times the amount
3. A 4-cylinder engine fires one cylinder at every ______________ degrees of crankshaft rotation. a. 27 b. 180 c. 120 d. 90
8. Typical journal-to-bearing clearance is ______________. a. 0.00015 to 0.00018 in. b. 0.0005 to 0.0025 in. c. 0.15 to 0.25 in. d. 0.02 to 0.035 in.
4. A splayed crankshaft is a crankshaft that ______________. a. Is externally balanced b. Is internally balanced c. Has offset main bearing journals d. Has offset rod journals 5. The thrust bearing surface is located on one of the main bearings to control thrust loads caused by ______________. a. Lugging the engine b. Torque converter or clutch release forces c. Rapid deceleration forces d. Both a and c
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9. A bearing shell has a slightly larger arc than the bearing housing. This difference is called ______________. a. Bearing crush b. Bearing tang c. Bearing spread d. Bearing saddle 10. Bearing ______________ occurs when a bearing shell is slightly above the parting surface of the bearing cap. a. Overlap b. Crush c. Cap lock d. Interference fit
chapter
GASKETS AND SEALANTS
36 OBJECTIVES: After studying Chapter 36, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “C” (Engine Block Diagnosis and Repair). • Describe the various types of gaskets. • Explain why the surface finish is important for head gaskets. • List the types of sealers and their applications. • Explain the use and precautions associated with cover gaskets. KEY TERMS: Anaerobic sealers 386 • Armor 381 • Fire ring 381 • Formed in place gaskets (FIPG) 384 • Fretting 384 • Multilayered steel (MLS) gaskets 381 • No-retorque-type gaskets 381 • Perforated steel core gaskets 381 • Room-temperature vulcanization (RTV) 385 • Rubber-coated metal (RCM) gaskets 384
load on the head gasket just when the greatest seal is needed.
INTRODUCTION NEED FOR GASKETS AND SEALANTS
Gaskets and sealants are used in engines to seal gaps and potential gaps between two or more parts. Gaskets and sealants must be able to withstand:
Temperatures to which the engine part may be exposed during normal operation
Vibrations produced in the engine and the accessories that are attached to the engine
Acids and other chemicals that are found in and throughout an engine
Expanding and contracting at different rates (They must be able to seal even though the two parts are expanding and contracting at different rates as the engine is started at low temperature all the way to normal operating temperature and repeating this cycle every time the engine is operated.)
SEE FIGURE 36–1.
HEAD GASKETS REQUIREMENTS NEEDED
The head gasket is under the highest clamping loads. It must seal passages that carry coolant and often is required to seal a passage that carries hot engine oil. The most demanding job of the head gasket is to seal the combustion chamber. As a rule of thumb, about 75% of the head bolt clamping force is used to seal the combustion chamber. The remaining 25% seals the coolant and oil passages. SEE FIGURE 36–2. The gasket must seal when the temperature is as low as –40°F (–40°C) and as high as 400°F (204°C). The combustion pressures can get up to 1,000 PSI (6,900 kPa) on gasoline engines. Cylinder head bolts are tightened to a specified torque, which stretches the bolt. The following forces are applied to a head gasket.
The combustion pressure tries to push the head upward and the piston downward on the power stroke. This puts additional stress on the head bolts and it reduces the clamping
A partial vacuum during the intake stroke tries to pull the head down against the gasket.
As the crankshaft rotates, the force on the head changes from pressure on the combustion stroke to vacuum on the intake stroke, then back to pressure.
Newer engines have lightweight thin-wall castings. The castings are quite flexible, so that they move as the pressure in the combustion chamber changes from high pressure to vacuum. The gasket must be able to compress and recover fast enough to maintain a seal as the pressure in the combustion chamber changes back and forth between pressure and vacuum. As a result, head gaskets are made of several different materials that are assembled in numerous ways, depending on the engine. NOTE: Older head gasket designs often contained asbestos and required that the head bolts be retorqued after the engine had been run to operating temperature. Head gaskets today are dense and do not compress like those older-style gaskets. Therefore, most head gaskets are called no-retorque-type gaskets, meaning the cylinder head bolts do not have to be retorqued after the engine has run. New gaskets do not contain asbestos.
TYPES OF HEAD GASKETS
Perforated steel core gaskets. A perforated steel core gasket uses a wire mesh core with fiber facings. Another design has rubber-fiber facings cemented to a solid steel core with an adhesive. SEE FIGURES 36–3 AND 36–4. The thickness of the gasket is controlled by the thickness of the metal core. The facing is thick enough to compensate for minor warpage and surface defects. The fiber facing is protected around the combustion chamber with a metal armor (also called a fire ring). SEE FIGURE 36–5. The metal also increases the gasket thickness around the cylinder so that it uses up to 75% of the clamping force and forms a tight combustion seal.
Multilayered steel gaskets. The multilayered steel (MLS) gaskets are constructed in the following manner.
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THERMOSTAT HOUSING GASKET
INTAKE MANIFOLD END SEALS
CYLINDER HEAD GASKET
INTAKE MANIFOLD GASKET
VALVE COVER GASKET
WATER PUMP GASKET
TIMING COVER GASKET
EXHAUST MANIFOLD GASKET
FRONT CRANKSHAFT SEAL OIL PAN GASKET
FIGURE 36–1 Gaskets are used in many locations in the engine.
INTAKE MANIFOLD GASKET
EXHAUST MANIFOLD GASKET
VALVE COVER GASKET
STEEL CORE
HEAD GASKET
FIGURE 36–2 Gaskets help prevent leaks between two surfaces.
Three to five layers of stainless steel sheet are separated by elastomer (rubber) material.
The elastomer material is between the layers of the sheet metal and on both surfaces.
The multiple layers of metal provide a springlike effect to the gasket, which allows it to keep the combustion chamber sealed. The many layers of thin steel reduce bore and overhead camshaft distortion with less clamping force loss than previous designs. SEE FIGURE 36–6.
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SOFT FACING
FIGURE 36–3 A typical perforated steel core head gasket with a graphite or composite facing material.
The use of multilayered steel gaskets also reduces the torque requirement and, therefore, reduces the stresses on the fastener and engine block. MLS gaskets are used in most engines that use aluminum cylinder heads and cast-iron blocks. The use of MLS head gaskets requires that both the head and the block deck surface have a smooth surface finish of 15 to 30 microinches. This smooth surface finish allows the head to move slightly during operation and not damage the gasket.
BONDING ADHESIVE TEFLON ® COATING RUBBER FIBER FACING STEEL CORE
FIGURE 36–4 A solid steel core head gasket with a nonstick coating, which allows some movement between the block and the head, and is especially important on engines that use cast-iron blocks with aluminum cylinder heads.
FIGURE 36–7 Left to right: Cork-rubber, paper, composite, and synthetic rubber (elastomer) gaskets. TECH TIP Wow! I Can’t Believe a Cylinder Can Deform That Much! An automotive instructor used a dial bore gauge in a 4-cylinder, cast-iron engine block to show students how much a block can deform. Using just one hand, the instructor was able to grasp both sides of the block and then squeeze it. The dial bore gauge showed that the cylinder deflected about 0.0003 in. (3/10,000 of an inch) just by squeezing the block with one hand—and that was with a cast-iron block! After this demonstration, the students were more careful during engine assembly and always used a torque wrench on each and every fastener that was installed in or on the engine block.
STEEL OR COPPER WIRE RING
FIGURE 36–5 The armor ring can be made from steel or copper.
LAYERS OF THIN STEEL
FIGURE 36–6 Multilayer steel (MLS) gaskets are used on many newer all-aluminum engines as well as on engines that use a cast block with aluminum cylinder heads. This type of gasket allows the aluminum to expand without losing the sealing ability of the gasket.
COVER GASKET MATERIALS
CORK GASKETS
Older engines often used gaskets made from cork. Cork is the bark from a Mediterranean cork oak tree. It is made of very small, flexible, 14-sided, air-filled fiber cells, about 0.001 in. (0.025 mm) in size. Disadvantages of cork gaskets include the following:
Because cork is mostly wood, it expands when it gets wet and shrinks when it dries. This causes cork gaskets to change in size when they are in storage and while installed in the engine.
Oil gradually wicks through the organic binder of the cork, so a cork gasket often looks like it is leaking.
Problems with cork gaskets led the gasket industry to develop cork cover gaskets using synthetic rubber as a binder for the cork. This type of gasket is called a cork-rubber gasket. These cork-rubber gaskets are easy to use, and they outlast the old cork gaskets.
FIBER GASKETS
Some oil pans use fiber gaskets. Covers with higher clamping forces use gaskets with fibers that have greater density. For example, timing covers may have either fiber or paper gaskets.
COVER GASKET REQUIREMENTS
Cover gaskets are used to seal valve covers, oil pans, timing chain and other covers. The gasket must be impermeable to the fluids it is designed to seal in or out. The gasket must conform to the shape of the surface, and it must be resilient, or elastic, to maintain the sealing force as it is compressed. Gaskets work best when they are compressed about 30%.
SYNTHETIC RUBBER GASKETS Molded, oil-resistant synthetic rubber is being used in more applications to seal covers. When it is compounded correctly, it forms a superior cover gasket. It operates at high temperatures for a longer period of time than does a cork-rubber cover gasket. SEE FIGURE 36–7.
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383
METAL COMPRESSIONLIMITING WASHER SILICONE RUBBER SEAL
FIGURE 36–8 Rubber-coated steel gaskets have replaced many oil pan gaskets that once had separate side rail gaskets and end seals.
NYLON PLASTIC
FIGURE 36–10 A typical intake manifold gasket showing the metal washer at each fastener location which keeps the gasket from being compressed too much.
FORMED IN PLACE GASKETS
FIGURE 36–9 Formed in place gaskets often use silicone rubber and are applied at the factory using a robot. Check gasket manufacturers for the correct gasket replacement. TECH TIP Rubber and Contact Cement One of the reasons why gaskets fail is due to their movement during installation. Some gaskets, such as cork or rubber valve cover gaskets or oil pan gaskets, can be held onto the cover using a rubber or contact cement. To use a rubber or contact cement, use the following steps. STEP 1
Apply a thin layer to one side of the gasket and to the cover where the gasket will be placed.
STEP 2
Allow the surfaces to air dry until touch free.
STEP 3
Carefully place the gaskets onto the cover being sure to align all of the holes.
CAUTION: Do not attempt to remove the gasket and reposition it. The glue is strong and the gasket will be damaged if removed. If the gasket has been incorrectly installed, remove the entire gasket, clean the gasket surface, and repeat the installation using a new gasket.
Formed in place gaskets (FIPG) are commonly used because they can be applied at the engine plant using a robot. The sealing material is extruded and placed onto the sealing surface and then the two parts being sealed are placed together and the fasteners tightened. When FIPG are being replaced during an engine repair or overhaul, check service information for the exact gasket material to use. SEE FIGURE 36–9.
PLASTIC/RUBBER GASKETS
Most intake manifold gaskets use a nylon (usually nylon 6.6) reinforced body with silicone rubber sealing surfaces. The nylon is used for two reasons. 1. It provides a thermal barrier to help stop the heat from the cylinder heads to flow to the intake manifold. This helps keep the intake air cooler, resulting in increased engine power. 2. The nylon plastic is strong and provides a stable foundation for the silicone rubber seal.
SEE FIGURE 36–10.
GASKET FAILURES CAUSES OF GASKET FAILURE
Gaskets can fail to seal properly, but the root cause is often a severe condition. A head gasket can fail for the following reasons.
Detonation (spark knock or ping) may cause extreme pressure to be exerted on the armor of the head gasket, causing it to deform.
A plugged PCV system can increase crankcase pressure resulting in engine gasket failures such as oil pan, valve cover, timing cover, and main oil seals.
Improper installation such as incorrect torquing sequence can cause gasket failure.
RUBBER-COATED METAL GASKETS
The rubber-coated metal (RCM) gasket uses a metal core to give strength to the gasket. The metal is coated with a layer on both sides with silicone rubber and molded in sealing beads. RCM gaskets are used in many places, including:
Water pump gaskets
Valve cover gaskets
Oil pan gaskets
SEE FIGURE 36–8.
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FRETTING
Fretting is a condition that can destroy intake manifold gaskets, caused by the unequal expansion and contraction of two different engine materials. For example, if the intake manifold is constructed of aluminum and the cylinder heads are cast iron, the intake manifold will expand more than the cylinder heads. This
FIGURE 36–11 This intake manifold gasket was damaged due to fretting. Newer designs allow for more movement between the intake manifold and the cylinder head.
TECH TIP
OIL PAN
REAR MAIN SEAL
CRANKSHAFT
FIGURE 36–12 A rear main seal has to be designed to seal oil from leaking around the crankshaft under all temperature conditions.
Hints for Gasket Usage 1. Never reuse an old gasket. A used gasket or seal has already been compressed, has lost some of its resilience, and has taken a set. If a used gasket does reseal, it will not seal as well as a new gasket or seal. 2. A gasket should be checked to make sure it is the correct gasket. Also check the list on the outside of the gasket set to make sure that the set has all the gaskets that may be needed before the package is opened. 3. Read the instruction sheet. An instruction sheet is included with most gaskets. It includes a review of the things the technician should do to prepare and install the gaskets, to give the best chance of a good seal. The instruction sheet also includes special tips on how to seal spots that are difficult to seal or that require special care to seal on a particular engine.
causes a shearing effect, which can destroy the gasket. Therefore, before assembling an engine, check for the latest design gaskets that are often different from the type originally used in the engine. SEE FIGURE 36–11.
OIL SEALS PURPOSE AND FUNCTION
Oil seals allow the shaft to rotate and seal the area around the shaft to prevent oil or coolant from leaking. Seals come in varied sizes and styles.
SEAL MATERIALS
Most seals use a steel backing for strength and a variety of sealing materials, including:
Buna-N
Viton® (fluorocarbon)
Teflon® (polytetrafluorethylene, also called PTFE)
SEE FIGURE 36–12.
TECH TIP Always Check the VIN There are so many variations in engines that it is important that the correct gasket or seal be used. For example, a similar engine may be used in a front-wheel-drive or a rear-wheel-drive application and this could affect the type or style of gasket or seal used. For best results, the wise technician should know the vehicle identification number (VIN) when ordering any engine part.
CAUTION: Do not use oil on a Teflon® seal because this type of seal requires that some of the material be transferred to the rotating shaft to seal properly. If oil is used on the seal, the seal will leak.
ASSEMBLY SEALANTS RTV SILICONE
RTV silicone is used by most technicians in sealing engines. RTV, or room-temperature vulcanization, means that the silicone rubber material will cure at room temperature. It is not really the temperature that causes RTV silicone to cure, but the moisture in the air. RTV silicone cures to a tack-free state in about 45 minutes. It takes 24 hours to fully cure. RTV silicone is available in several different colors. The color identifies the special blend within a manufacturer’s product line. Equal grades of silicone made by different manufacturers may have different colors. RTV silicone can be used in two ways in engine sealing. 1. It can be used as a gasket substitute between a stamped cover and a cast surface. 2. It is used to fill gaps or potential gaps. A joint between gaskets or between a gasket and a seal is a potential gap.
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RTV SEALER
ANAEROBIC SEALER
FIGURE 36–14 Anaerobic sealer is used to seal machined surfaces. Always follow the instructions on the tube for best results.
UE BL
HAND TOOL REMOVABLE THREADLOCKING
SURFACE WHERE STAMPED VALVE COVER IS SEATED
RTV precautions include: 1. Some RTV silicone sealers use acetic acid, and the fumes from this type can be drawn through the engine through the PCV system and cause damage to oxygen sensors. Always use an amine-type RTV silicone or one that states on the package that it is safe for oxygen sensors. 2. RTV should not be used with a gasket as a sealer because it is slippery and could easily cause the gasket to move out of proper location. 3. RTV silicone should never be used around fuel because the fuel will cut through it. Silicone should not be used as a sealer on gaskets. It will squeeze out to leave a bead inside and a bead outside the flange. The inside bead might fall into the engine, plugging passages and causing engine damage. The thin film still remaining on the gasket stays uncured, just as it would be in the original tube. The uncured silicone is likely to let the gasket or seal slip out of place. SEE FIGURE 36–13.
ANAEROBIC SEALERS Anaerobic sealers cure in the absence of air. They are used as thread lockers (such as Loctite®), and they are used to seal rigid machined joints between cast parts. Anaerobic sealers lose their sealing ability at temperatures above 300°F (149°C). On production lines, the curing process is speeded up by using ultraviolet light. When the anaerobic sealer is used on threads, air does not get to it so it hardens to form a seal to prevent the fastener from loosening. Anaerobic sealers can be used to seal machined surfaces without a gasket. The surfaces must be thoroughly clean to get a good seal. Special primers are recommended for use on the sealing surface to get a better bond with anaerobic sealers. SEE FIGURES 36–14 AND 36–15.
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RE D
FIGURE 36–13 Room-temperature vulcanization (RTV) is designed to be a gasket substitute on nonmachined surfaces. Be sure to follow the instructions as printed on the tube for best results.
HIGH STRENGTH THREADLOCKING
FIGURE 36–15 The strength of the thread locker depends on whether the fastener is to be removed by hand (blue). High-strength thread locker (red) can only be removed if heated.
NONHARDENING SEALERS Sealers are nonhardening materials. Examples of sealer trade names include:
Form-A-Gasket 2
Pli-A-Seal
Tight Seal 2
Aviation Form-A-Gasket
Brush Tack
Copper Coat
Spray Tack
High Tack
Sealers are always used to seal the threads of bolts that break into coolant passages. Sealers for sealing threads may include Teflon. Sealer is often recommended for use on shim-type head gaskets and intake manifold gaskets. These gaskets have a metal surface that does not conform to any small amounts of surface roughness on the sealing surface. The sealer fills the surface variations between the gasket and the sealing surface. Sealer may be used as a sealing aid on paper and fiber gaskets if the gasket needs help with sealing on a scratched, corroded, or rough surface finish. The sealer may be used on one side or on both sides of the gasket. CAUTION: Sealer should never be used on rubber or corkrubber gaskets. Instead of holding the rubber gasket or seal, it will help the rubber to slip out of place because the sealer will never harden.
ANTISEIZE COMPOUNDS Antiseize compounds are used on fasteners in the engine that are subjected to high temperatures to prevent seizing caused by galvanic action between dissimilar metals. These compounds minimize corrosion from moisture. Exhaust manifold bolts or nuts, and oxygen sensors, keep them from seizing. The antiseize compound minimizes the chance of threads being pulled or breaking as the oxygen sensor is removed. Always follow the vehicle manufacturer’s recommendations found in service information. SEE FIGURE 36–16. SEALANT SUMMARY
SEE CHART 36–1.
FIGURE 36–16 Applying antiseize compound to the threads of a bolt helps prevent the threads from galling or rusting.
PRODUCTS
COMMON TRADE NAMES
USES
EXAMPLES
RTV (room-temperature vulcanization)
Silicone
As a gasket substitute or fill gaps
Valve covers, oil pans, intake manifold end seals, timing covers, transmission pans
Anaerobic sealer (threadlocker) medium strength
Loctite® Blue
Keeps fasteners from vibrating loose
For nut and bolt applications 1/4 to 3/4 in. (6 to 20 mm)
Anaerobic sealer (threadlocker) high temperature, high strength
Loctite® Red
Heavy-duty applications
For larger fasteners 3/8 to 1 in. (9.5 to 25 mm)
Antiseize (general purpose)
NeverseezTM Kopr KoteTM E-Z BreakTM
For preventing corrosion seizing
Oxygen sensors, spring bolts, exhaust manifold bolts/nuts
Antiseize (nickel)
NeverseezTM Thred-GardTM
For stainless steel and other metal applications
Harsh chemical environments
Hardening gasket sealant
Permatex® #1
Holds gaskets in place during assembly; also seals paper and cork gaskets
Transmission and engine oil pan gaskets, timing cover (paper gaskets) valve cover gaskets, and intake manifold gaskets
Nonhardening sealant
Permatex® #2
Allows repeated disassembly and reassembly
Thermostat housings, differential coverings, intake manifolds, fuel injectors and fuel pumps, transmission and torque converter seals
Aviation cement/contact cement
Aviation Form-A-Gasket #3TM
Holds gaskets in place for assembly
All types of hoses and gaskets
CHART 36–1 Summary chart showing where sealants are used and their common trade names.
REVIEW QUESTIONS 1. What is the purpose of a gasket?
3. Why is armor used in head gaskets?
2. What are the types of cover gaskets?
4. What is the difference between RTV and anaerobic sealers?
CHAPTER QUIZ 1. What force causes a head gasket to be drawn downward during engine operation? a. Intake stroke vacuum b. Gravity c. Head bolt torque d. Exhaust gas pressure
2. Where is a multilayered steel (MLS) gasket most often used in an engine? a. Valve cover gasket b. Oil pan gasket c. Head gasket d. Intake manifold gasket
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3. A steel or copper wire used in a head gasket around the cylinder is called ______________. a. Armor c. Ridge block b. Fire ring d. Either a or b
7. Which type of oil seal must not have oil applied for it to work correctly? a. Silicone rubber c. Teflon® b. Buna-N d. Viton®
4. A one-piece oil pan gasket often uses ______________ in the middle to add strength. a. Plastic (nylon) c. Hard rubber b. Steel d. Carbon fiber
8. Which type of sealer is to be used on nonmachined surfaces? a. RTV c. Either a or b b. Anaerobic sealer d. Neither a nor b
5. Some gaskets use a steel washer around each bolt hole. The purpose of this washer is to ______________. a. Improve the strength of the gasket b. Help seal around the bolt hole c. Help prevent the gasket from shrinking d. Prevent the gasket from being overly compressed 6. A gasket failure caused by the movement of dissimilar materials is called ______________. a. Fretting c. Collapsing b. Corrosion d. Tearing
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37
9. Which product requires heat to remove? a. Red thread locker b. Blue thread locker c. RTV d. Antiseize 10. What precautions should be followed when using gaskets? a. Never reuse an old gasket. b. A gasket should be checked to make sure it is the correct gasket. c. Read the instruction sheet. d. All of the above
ENGINE ASSEMBLY AND DYNAMOMETER TESTING
OBJECTIVES: After studying Chapter 37, the reader should be able to: • Describe the steps that should be followed in preparation for assembly. • Explain clamping force. • Define the torque-to-yield method of fastener tightening. • Discuss the advantages of performing a trial assembly of the engine. • List the steps needed to assemble an engine. • Describe what dynamometer testing can determine about the engine. KEY TERMS: Assembly lube 392 • Clamping force 402 • Corrected torque 411 • Correction factor 411 • Dry bulb temperature 411 • Expansion plugs 393 • Fogging oil 392 • Freeze plugs 393 • Lash 406 • Piston ring compressor 399 • Soft core plugs 393 • Torque-to-yield (TTY) 403 • Transducers 411 • Welsh plugs 393
DETAILS, DETAILS, DETAILS Successful engine assembly depends on getting all of the details right. Where to start? Start when all parts have been purchased or prepared for assembly. When starting to assemble the engine, be sure to have all of the instructions from all of the parts used.
Read. Read all instructions that are included with all new parts and gaskets. Often very important information or suggested specifications are included and may be at the end. Understand. Be sure to fully understand everything that is stated in the instructions. If unsure as to what is meant, ask a knowledgeable technician or call the company to be sure that all procedures are clearly understood. This is especially important if working on an engine that is not very common, such as the Audi/Volkswagen W-8. This engine has seven rotating shafts, including:
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Four overhead camshafts
Two counterrotating balance shafts
One crankshaft
The block and cylinder arrangement is also unique. SEE FIGURE 37–1.
Follow. Be sure to follow all of the instructions. Do not pick the easy procedures and skip others.
SHORT BLOCK PREPARATION ITEMS TO CHECK
The following engine block details should
be checked.
All passages should be clean and free of rust and debris.
All gasket surfaces are properly cleaned and checked for burrs and scratches.
ENGINE BLOCK
CYLINDERS
ENGINE PART MATERIAL
GASKET MATERIAL
ACCEPTABLE SURFACE FINISH (RA)
Cast iron/cast iron
Composite
60 to 80 μin.
Aluminum/cast iron
Composite
20 to 30 μin.
Aluminum/cast iron
Rubber-coated multilayered steel (MLS)
15 to 30 μin.
CHART 37–1 The surface finish of the block and cylinder head depends on the type of gasket being used.
Surface too smooth. If the surface finish is too smooth, the gasket can move out of proper location, causing leakage.
Surface finish is measured in microinches, usually abbreviated by using the Greek letter mu (μ) and the abbreviation for inches together (μin.). FIGURE 37–1 A uniquely designed W-8 engine installed in some Audi and Volkswagen vehicles. Rebuilding the engine would require detailed service information to be sure that all steps are taken for proper assembly.
The higher the microinch finish, the rougher the surface.
The lower the microinch finish, the smoother the surface. The specification for surface finish is usually specified in roughness average, or Ra.
SEE CHART 37–1 for the acceptable roughness for the head gasket surface. Check the instruction sheet that comes with the gasket for the specified surface finish.
CHECKING SURFACES BEFORE ASSEMBLY All surfaces of an engine should be clean and straight and have the specified surface finish and flatness. Flatness is a measure of how much the surface varies in any 6 in. span. An industry standard maximum limit for flatness is usually 0.002 in. If the surface is not flat, the gaskets will not be able to seal properly.
FIGURE 37–2 Deburring all sharp edges is an important step to achieve proper engine assembly.
All cups and plugs should be installed.
The final bore dimension is correct for the piston.
The surface finish of the cylinder bore matches with the specified finish required for the piston rings that are going to be used.
All sharp edges and burrs have been removed. SEE FIGURE 37–2.
The main bearing bores (saddles) are straight and inline.
The lifter bores have been honed and checked for proper dimension.
SURFACE FINISH
The surface finish is important for the proper
sealing of any gasket.
Surface too rough. If the surface finish is too rough, the gasket will not be able to seal the deep grooves in the surface.
PREPARING THE BLOCK FOR STUDS Using studs instead of head bolts for cylinder heads is recommended for all high-performance applications. However, studs should not be used on a street-driven vehicle engine, because the studs would prevent the cylinder heads from being removed unless the engine is first removed from the vehicle. Most vehicles do not have enough room under the hood to allow the cylinder heads to be moved upward far enough for removal. Studs provide for more accurate and consistent torque loading and clamping force. For example, when a bolt is used to attach a cylinder head, it is being twisted and pulled at the same time. In comparison, a stud is only being stretched. Also, a stud uses a fine thread for the retaining nut, which allows for more precise torque readings. SEE FIGURE 37–3. The use of studs for the main bearing saddles helps main cap alignment, because the torque applied is more consistent and there is less chance of the bearing cap moving during the tightening operation. SEE FIGURE 37–4. Screw the studs into the block but finger tighten only. Do not tighten a stud more than finger tight. A nut should not be used to double nut a stud to keep it in position. NOTE: The tightening torque in the installation instructions is for the nut and not the stud itself. In most cases, a thread locker such as Loctite® 242 can be used on the threads of the stud being inserted into the block to make the installation of the stud more permanent.
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FIGURE 37–3 Studs installed in the block, replacing head bolts. FIGURE 37–5 A Cadillac Northstar engine being rebuilt. The shop doing the work is installing Heli-coils® in all threaded cylinder head bolt holes as a precaution. Using duct tape to cover the engine helps prevent aluminum chips from getting into passages.
FIGURE 37–4 Main bearing studs installed on a V-8 block.
TECH TIP Be Aware of BMW Engine Procedures If rebuilding a BMW engine, check service information carefully because most BMW engines require that threaded inserts be installed in all head bolt threads. Performing this operation can increase the cost and time needed. Always follow all recommended service procedures on the engine being serviced. SEE FIGURE 37–5.
FIGURE 37–6 A thread chaser (top) is the preferred tool to clean threaded holes because it cleans without removing metal compared to a tap (bottom).
STEP 2
Check that all liquid has been removed from the bolt holes in the block. If liquid is in the bottom of a blind hole, the block can be cracked when the bolt is installed.
CAUTION: If a thread locker is used, be sure to immediately install the main bearing caps before the compound cures to help avoid misalignment.
PREPARING THREADED HOLES STEP 1
390
All threads in the block should be thoroughly cleaned. Many experts recommend using a thread chaser, because a tap could cut and remove metal. A chaser will restore the threads without removing metal. SEE FIGURE 37–6.
CHAPTER 3 7
CYLINDER HEAD PREPARATION ITEMS TO CHECK
Check the following details on the cylinder
head(s).
The surface finish of the fire deck is as specified for the head gasket type to be used.
FIGURE 37–7 Using a plastic trash bag is an excellent way to keep the engine clean during all stages of assembly.
FIGURE 37–8 A trial assembly showed that some grinding of the block will be needed to provide clearance for the counterweight of the crankshaft. Also, notice that the engine has been equipped with studs for the four-bolt main bearing caps.
TECH TIP INTERNAL OIL PASSAGES
Keep the Engine Covered Using a large plastic trash bag is an excellent way to keep the engine clean when storing it between work sessions. SEE FIGURE 37–7.
All valves should be checked for leakage by pouring mineral spirits into the intake and exhaust parts and look for leakage past the valves. All valve springs should be checked for even spring pressure and installed height. Check for proper pushrod length. If the cylinder head(s) has been machined and/or the block deck machined, the pushrods may be too long. If the pushrods are too long, the rocker arm geometry will not be correct. One problem that can occur with incorrect rocker arm geometry is spring bind, which can cause severe engine damage. If replacement rocker arms are used, be sure that the geometry and total lift will be okay.
TRIAL ASSEMBLY SHORT BLOCK Before performing final engine assembly, the wise technician checks that all parts will fit and work. This is especially important if using a different crankshaft that changes the stroke. SEE FIGURE 37–8 for an example of a 400 cu. in. Chevrolet crankshaft being fitted to a 350 cu. in. Chevrolet engine. VALVE TRAIN
Another place where a trial fit is needed is in the valve train. Some timing chain mechanisms require more space than the stock component so some machining may be needed. If the rocker arms have been upgraded to roller rockers, these should be installed and checked that the tip of the roller rests at the center of the valve stem. SEE FIGURE 37–9.
NEEDLE ROLLER BEARINGS
SPRING OILER HOLE
CAGED NEEDLE ROLLER BEARINGS
FIGURE 37–9 A typical high-performance aftermarket rocker arm which is equipped with needle roller bearings at the valve stem end and caged needle bearing at the pivot shaft end to reduce friction, which increases engine horsepower and improves fuel economy.
REAL WORLD FIX Valve Springs Can Vary A technician was building a small block Chevrolet V-8 engine at home and was doing the final detailed checks, and found that many of the valve springs did not have the same tension. Using a borrowed valve spring tester, the technician visited a local parts store and measured all of the valve springs that the store had in stock. The technician selected and purchased the 16 valve springs that were within specification and within a very narrow range of tension. Although having all valve springs equal may or may not affect engine operation, the technician was pleased that all of the valve springs were equal.
If there is a problem, further investigation will be needed because the pushrods may be too long due to machining of the block deck and/ or cylinder head. Rotate the engine and check for proper clearance throughout the entire opening and closing of the valves. Use a feeler gauge between the coils of the valve spring to check for coil bind. If coil bind occurs, a different camshaft or valve spring should be used.
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FIGURE 37–12 An angle gauge being used to check the angle between the cylinder heads on this small block Chevrolet V-8 engine.
FIGURE 37–10 Fogging oil is used to cover bare metal parts when the engine is being stored to prevent corrosion.
FIGURE 37–13 The best way to thoroughly clean cylinders is to use soap (detergent), water, and a large washing brush. This method floats the machining particles out of the block and washes them away.
FIGURE 37–11 Engine assembly lube is recommended to be used on engine parts during assembly.
CHECK THE ANGLE BETWEEN HEADS During the trial assembly, use a gauge to check that the heads are at the correct angle to ensure proper intake manifold gasket sealing. If the angle is not correct, then remachining of the head or block will be needed. SEE FIGURE 37–12.
TECH TIP Fogging Oil and Assembly Lube When assembling an engine, the parts should be coated with a light oil film to keep them from rusting. This type of oil is commonly referred to as fogging oil and is available in spray cans. SEE FIGURE 37–10. During engine assembly, the internal parts should be lubricated. While engine oil or grease could be used, most experts recommend the use of a specific lubricant designed for engine assembly. This lubricant, designed to remain on the parts and not drip or run, is called assembly lube. SEE FIGURE 37–11.
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FINAL SHORT BLOCK ASSEMBLY BLOCK PREPARATION
All surfaces should be checked for damage resulting from the machining processes. Items that should be done before assembly begins include the following: 1. The block, including the oil gallery passages, should be thoroughly cleaned. SEE FIGURES 37–13 AND 37–14. 2. All threaded bolt holes should be chamfered. 3. All threaded holes should be cleaned with a thread chaser before final assembly.
CUP PLUGS
FIGURE 37–15 This engine uses many cup plugs to block off coolant and oil passages as well as a large plug over the end of the camshaft bore. FIGURE 37–14 All oil galleries should be cleaned using soap (detergent), water, and a long oil gallery cleaning brush.
INSTALLING CUPS AND PLUGS
Oil gallery plugs should be
installed using sealant on the threads. CAUTION: Avoid using Teflon tape on the threads of oil gallery plugs or coolant drain plugs. The tape is often cut by the threads, and thin strips of the tape are then free to flow through the oil galleries where the tape can cause a clog, thereby limiting lubricating engine oil to important parts of the engine. Core holes left in the external block wall are machined and sealed with soft core plugs or expansion plugs (also called freeze plugs or Welsh plugs). Soft plugs are of two designs.
Convex type. The core hole is counterbored with a shoulder. The convex soft plug is placed in the counterbore, convex side out. It is driven in with a fitted seating tool. This causes the edge of the soft plug to enlarge to hold it in place. A convex plug should be driven in until it reaches the counterbore of the core plug hole. Cup type. This most common type fits into a smooth, straight hole. The outer edge of the cup is slightly bell mouthed. The bell mouth causes it to tighten when it is driven into the hole to the correct depth with a seating tool. An installed cup-type soft plug is shown in FIGURE 37–15.
A cup plug is installed about 0.02 to 0.05 in. (0.5 to 1.3 mm) below the surface of the block, using sealant to prevent leaks. SEE FIGURE 37–16.
CAM BEARINGS
A cam bearing installing tool is required to insert the new cam bearing without damaging the bearing. A number of tool manufacturers design and sell cam bearing installation tools. Their common feature is a shoulder on a bushing that fits inside the cam bearing, with a means of keeping the bearing aligned as it is installed. The bearing is placed on the bushing of the tool and rotated to properly align the oil hole. The bearing is then forced into the bearing
FIGURE 37–16 Sealer should be applied to the cup plug before being driven into the block.
?
FREQUENTLY ASKED QUESTION
What Causes Premature Bearing Failure? According to a major manufacturer of engine bearings, the major causes of premature (shortly after installation) bearing failure include the following: Dirt (45%) Misassembly (13%) Misalignment (13%) Lack of lubrication (11%) Overloading or lugging (10%) Corrosion (4%) Other (4%) Many cases of premature bearing failure may result from a combination of several of these items. Therefore, to help prevent bearing failure, keep everything as clean as possible.
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TWO PIECE PULLER SCREW
EXPANDING COLLET
PULLING PLATE THRUST BEARING
BACK-UP NUT
BEARING
PULLING NUT EXPANDING MANDREL
FIGURE 37–17 Screw-type puller being used to install a new cam bearing. Most cam bearings are crush fit. The full round bearing is forced into the cam bearing bore. Most vehicle manufacturers specify that the cam bearings be installed “dry” without lubrication to help prevent them from spinning, which would cause the bearing to block the oil feed hole. bore of the block by either a pulling screw or a slide hammer. A pulling screw type of tool is illustrated in FIGURE 37–17. The installed bearing must be checked to ensure that it has the correct depth and that the oil hole is indexed with the oil passage in the block. No additional service is required on cam bearings that have been properly installed. The opening at the back of the camshaft is closed with a cup plug.
UPPER
THRUST BEARING
MEASURING MAIN BEARING CLEARANCE
The main bearings are properly fit before the crankshaft is lubricated or turned. The oil clearance of both main and connecting rod bearings is set by selectively fitting the bearings. In this way, the oil clearance can be adjusted to within 0.0005 in. of the desired clearance. CAUTION: Avoid touching bearings with bare hands. The oils on your fingers can start corrosion of the bearing materials. Always wear protective cloth or rubber gloves to avoid the possibility of damage to the bearing surface.
Bearings are usually made in 0.010, 0–020, and 0.030 in. undersize for use on reground journals. SEE FIGURE 37–18 for a typical main bearing set. The crankshaft bearing journals should be measured with a micrometer to select the required bearing size.
Each of the main bearing caps will only fit one location and the caps must be positioned correctly.
The correct-size bearings should be placed in the block and cap, making sure that the bearing tang locks into its slot.
The upper main bearing has an oil feed hole. The lower bearing does not have an oil hole.
Lower the crankshaft squarely so that it does not damage the thrust bearing. Carefully rest the clean crankshaft in the block on the upper main bearings.
After making sure that there is no oil on the crank journal of the bearing, place a strip of Plastigage® (gauging plastic) on each main bearing journal. Install the main bearing caps and tighten the bolts to specifications.
Remove each cap and check the width of the Plastigage® with the markings on the gauge envelope, as shown in FIGURE 37–19.
The width of the plastic strip indicates the oil clearance.
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LOWER
FIGURE 37–18 Typical main bearing set. Note that the upper halves are grooved for better oil flow and the lower halves are plain for better load support. This bearing set uses the center main bearing for thrust control. Notice that the upper bearing set has the holes for oil, whereas the lower set does not.
CORRECTING BEARING CLEARANCE
Oil clearances normally run from 0.0005 to 0.002 in. (half a thousandth to two thousandths).
The oil clearance can be reduced by 0.001 in. by replacing both bearing shells with bearing shells that are 0.001 in. undersize.
The clearance can be reduced by 0.0005 in. by replacing only one of the bearing shells with a bearing shell that is 0.001 in. smaller.
This smaller bearing shell should be placed in the engine block side of the bearing (the upper shell). Oil clearance can be adjusted accurately using this procedure. Try to avoid mismatching the bearing shells by more than a 0.001 in. difference in size.
LIP SEAL INSTALLATION Seals are always used at the front and rear of the crankshaft. Overhead cam engines may also have a seal at the front end of the camshaft and at the front end of an auxiliary accessory shaft. Either a lip seal or a rope seal is used in these locations. SEE FIGURE 37–20.
SEAL TOOL
DRIVER
FIGURE 37–21 Always use the proper driver to install a main seal. Never pound directly on the seal.
OIL SEAL GASKET
FIGURE 37–19 The width of the plastic gauging strip determines the oil clearance of the main bearing. An alternate method of determining oil clearance includes careful measurement of the crankshaft journal and bearings after they are installed and the main housing bore caps are torqued to specifications. SEAL RETAINER
FIGURE 37–22 The rear seal for this engine mounts to a retainer plate. The retainer is then bolted to the engine block. TECH TIP “One to Three”
FIGURE 37–20 Lip-type rear main bearing seal in place in the rear main bearing cap. The lip should always be pointing toward the inside of the engine. The rear crankshaft oil seal is installed after the main bearings have been properly fit. The lip seal may be molded in a steel case or it may be molded around a steel stiffener. The counterbore or guide that supports the seal must be thoroughly clean. In most cases, the back of the lip seal is dry when it is installed. Occasionally, a manufacturer will recommend the use of sealants behind the seal. Check service information for the specified sealing instructions. The lip of the seal should be well lubricated before the shaft and cap are installed. SEE FIGURES 37–21 AND 37–22. CAUTION: Teflon seals should not be lubricated. This type of seal should be installed dry. When the engine is first started, some of the Teflon transfers to the crankshaft, to create a Teflon-to-Teflon surface. Even touching the seal
When engine technicians are talking about clearances and specifications, the unit of measure most often used is thousandths of an inch (0.001 in.). Therefore, a clearance expressed as “one to three” would actually be a clearance of 0.001 to 0.003 in. The same applies to parts of a thousandth of an inch. For example, a specification of 0.0005 to 0.0015 in. would be spoken of as simply being “one-half to one and one-half.” The unit of a thousandth of an inch is assumed, and this method of speaking reduces errors and misunderstandings. HINT: Most engine clearance specifications fall within one to three thousandths of an inch. The written specification could be a misprint. Therefore, if the specification does not fall within this general range, double-check the clearance value using a different source.
with your hands could remove some of the outer coating on the seal and cause a leak. Carefully read, understand, and follow the installation instructions that come with the seal.
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FIGURE 37–23 Many engine builders prefer to stagger the parting lines of a rope-type seal.
ROPE SEAL INSTALLATION Some older engines use ropetype seals at both the front and rear of the crankshaft. Rope-type seals, usually called braided fabric seals, are sometimes used as rear crankshaft oil seals. Rope-type oil seals must be compressed tightly into the groove so that no oil can leak behind them. With the crankshaft removed, the upper half of the rope seal is put in a clean groove and compressed by rolling a round object against it to force it tightly into the groove. A piece of pipe, a large socket, or even a hammer handle can be used for this. When the seal is fully seated in the groove, the ends that extend above the parting surface are cut to be flush with the surface using a sharp single-edge razor blade or a sharp tool specially designed to cut the seal. Some technicians find that leaving a little of the seal higher than the bearing cap creates a better seal, because when the bearing cap is installed and tightened, the extra seal length forces the rope seal further into the groove. SEE FIGURE 37–23. CRANKSHAFT INSTALLATION
The main bearing caps and crankshaft should be removed after checking for proper bearing clearance. The surface of the bearings should then be given a thin coating of oil or assembly lubricant to provide initial lubrication for engine start-up. Install the crankshaft using the following steps. STEP 1
The crankshaft should be carefully placed in the bearings to avoid damage to the thrust bearing surfaces.
STEP 2
The bearing caps are installed with their identification numbers correctly positioned. The caps were originally machined in place, so they can only fit correctly in their original position.
STEP 3
The main bearing cap bolts are tightened finger tight, and the crankshaft is rotated. It should rotate freely.
THRUST BEARING CLEARANCE
Tighten all main bearing cap bolts to factory specification except for the bearing cap that is used for thrust (usually the center or the rear cap). Pry the crankshaft forward and rearward to align the cap half of the thrust bearing with the block saddle half. Most engine specifications for thrust bearing clearance (also called crankshaft end play) can range from 0.002 to
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FIGURE 37–24 A dial indicator is being used to check the crankshaft end play, known as thrust bearing clearance. Always follow the manufacturer’s recommended testing procedures.
FIGURE 37–25 A thrust bearing insert being installed before the crankshaft is installed. 0.012 in. (0.02 to 0.3 mm). This clearance or play can be measured with a:
Feeler gauge
Dial indicator SEE FIGURE 37–24.
If the clearance is too great, oversize main thrust bearings may be available for the engine. Semifinished bearings may have to be purchased and machined to size to restore proper tolerance. NOTE: Some engines use a separate replaceable thrust bearing. SEE FIGURE 37–25.
MAIN BEARING TIGHTENING PROCEDURE Tighten the main bearing caps to the specified assembly torque, and in the specified sequence. The procedure specified usually includes tightening the main bearing cap bolts in three stages.
Torque to one-third of the specified torque.
Then tighten to two-thirds of the specified torque.
Finally tighten the bolts to the factory specified torque.
Many manufacturers require that the crankshaft be pried forward or rearward during the main bearing tightening process. The crankshaft should turn freely after all main bearing cap bolts are fully torqued.
FIGURE 37–26 Installing a camshaft is easier if the engine is vertical so gravity can help, and this method reduces the possibility of damaging the cam bearings.
TECH TIP
FIGURE 37–27 A commercial additive designed to protect a flatbottom lifter camshaft used in older vehicles when using newer oils that do not have enough ZDDP to protect the camshaft and lifters.
TECH TIP
Use a Long Bolt to Hold the Camshaft
Two Choices If Using Flat-Bottom Lifters
To help install a camshaft without harming the cam bearings, install a long bolt into one of the end threaded holes in the camshaft. Then tilt the engine vertically so that gravity will cause the camshaft to fall straight down while holding onto the camshaft using the long bolt. SEE FIGURE 37–26.
An old or rebuilt engine that uses flat-bottom lifters must use one of two lubricants. 1. Oils that contain at least 0.15% or 1,500 parts per million (ppm) of zinc in the form of ZDDP. Oils that contain this much zinc are designed for off-road use only and in a vehicle that does not have a catalytic converter, such as racing oils. If the vehicle is equipped with a catalytic converter, replace the camshaft and lifters to roller type, so that newer oils with lower levels of zinc can be used. 2. Use a newer oil and an additive such as: a. GM engine oil supplement (EOS) (Part #1052367 or #88862586) b. Comp Cams® camshaft break-in oil additive (Part #159) c. Crane Cams® Moly Paste (Part #99002-1) d. Crane Cams® Super Lube oil additive (Part #99003-1) e. Lumati Assembly lube (Part #99010) f. Mell-Lube camshaft tube oil additive (Part # M-10012) g. Other available additives designed to protect the camshaft ( SEE FIGURE 37–27).
CRANKSHAFT ROTATING TORQUE It should never require over 5 pound-feet (lb-ft) (6.75 newton-meters, or N-m) of torque to rotate the crankshaft. An increase in the torque needed to rotate the crankshaft is often caused by a foreign particle that was not removed during cleanup. It may be on the bearing surface, on the crankshaft journal, or between the bearing and saddle.
INSTALLING THE CAMSHAFT PRELUBRICATION When the camshaft is installed, the lobes must be coated with a special lubricant that contains molydisulfide. This special lube helps to ensure proper initial lubrication to the critical cam lobe sections of the camshaft. Many manufacturers recommend multiviscosity engine oil such as SAE 5W-30 or SAE 10W-30. Some camshaft manufacturers recommend using straight SAE 30 or SAE 40 engine oil and not a multiviscosity oil for the first oil fill. Some manufacturers also recommend the use of an antiwear additive such as zinc dithiophosphate (ZDP).
NOTE: Some manufacturers recommend that a new camshaft always be installed when replacing valve lifters. 3. Never use a hydraulic lifter camshaft with solid lifters or hydraulic lifters with a solid lifter camshaft.
CAMSHAFT PRECAUTIONS
Whenever repairing an engine, follow these rules regarding the camshaft and lifters. 1. When installing a new camshaft, always install new valve lifters (tappets). 2. When installing new lifters, if the original cam is not excessively worn and if the pushrods all rotate with the original camshaft, the camshaft may be reused.
PISTON/ROD INSTALLATION CHECKING PISTON RINGS Before installing the piston assemblies, all piston rings should be checked for proper side clearance and ring gap. SEE FIGURE 37–28.
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NOTCH
FIGURE 37–28 A feeler gauge is used to check piston ring gap.
PISTON DIAMETER
RING GAP
2 to 3 in.
0.007 to 0.018 in.
3 to 4 in.
0.01 to 0.02 in.
4 to 5 in.
0.013 to 0.023 in.
FIGURE 37–29 The notch on a piston should always face toward the front of the engine.
CHART 37–2 The approximate ring gap based on the size of the bore in inches. Always check service information for the exact specifications for the engine being assembled.
Typical ring gap clearances are about 0.004 in. per inch of cylinder bore. SEE CHART 37–2. NOTE: If the gap is greater than recommended, some engine performance is lost. However, too small a gap will result in scuffing, because ring ends can be forced together during operation, which forces the rings to scrape the cylinders.
If the ring gap is too large, the ring should be replaced with one having the next oversize diameter.
If the ring gap is too small, the ring should be removed and filed to make the gap larger.
PISTON MARKINGS
Care must be taken to ensure that the pistons and rods are in the correct cylinder. They must face in the correct direction. There is usually a notch on the piston head indicating the front. Using this will correctly position the piston pin offset toward the right side of the engine. SEE FIGURE 37–29.
The connecting rod identification marks on pushrod 4 and 6 cylinder inline engines are normally placed on the camshaft side. On V-type engines, the connecting rod cylinder identification marks are on the side of the rods that can be seen from the bottom of the engine when the piston and rod assemblies are installed in the engine. Make sure the connecting rod has been installed on the piston correctly—the chamfer on the side of the big end should face outward (toward the crank throw). SEE FIGURE 37–30. Check service information for any special piston and rod assembly instructions.
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CHAMFER
FIGURE 37–30 On V-type engines that use paired rod journals, the side of the rod with the large chamfer should face toward the crank throw (outward).
CONNECTING ROD BEARING CLEARANCE
The rod cap, with the bearing in place, is put on the rod. There are two methods that can be used to check for proper connecting rod bearing clearance.
Use Plastigage® following the same procedure discussed for main bearing clearance.
Measure the assembled connecting rod big end devices with the bearing installed and the caps torqued to specification. Subtract the diameter of the rod journal to determine the bearing clearance. SEE FIGURE 37–31.
NOTE: Be certain to check for piston-to-crankshaft counterweight clearance. Most manufacturers specify a minimum 0.06 in. (1.5 mm).
PISTON INSTALLATION
To install a piston, perform the fol-
lowing steps. STEP 1
Apply a coating of clean engine oil to the cylinder walls. This oil should be spread over the entire cylinder wall surface by hand.
STEP 2
Apply oil or assembly lube to the rod bearings.
STEP 3
Align the piston ring gaps (ring gap stagger) to the locations specified in service information. SEE FIGURE 37–32.
CONNECTING ROD
FIGURE 37–33 A gapless ring is made in two pieces that overlap.
TIGHTENING HANDLE CONNECTING ROD BEARING INSIDE MICROMETER
FIGURE 37–31 An inside micrometer can be used to measure the inside diameter of the big end of the connecting rod with the bearings installed. This dimension subtracted from the rod journal diameter is equal to the bearing clearance.
UPPER OIL RING SIDE RAIL GAP
SECOND (NO. 2) COMPRESSION RING GAP
RATCHET
FIGURE 37–34 This style of ring compressor uses a ratchet to contract the spring band and compress the rings into their grooves.
PISTON PIN FRONT
TOP (NO. 1) COMPRESSION RING GAP (OIL RING EXPANDER GAP)
LOWER OIL RING SIDE RAIL GAP
FIGURE 37–32 One method of piston ring installation showing the location of ring gaps. Always follow the manufacturer’s recommended method for the location of ring gaps and for ring gap spacing.
STEP 4
Using a squirt-type oil can, squirt oil over the rings and the skirt of the piston. NOTE: Special types of piston rings (overlapping or gapless) are installed dry, without oil. SEE FIGURE 37–33. Some manufacturers recommend oiling only the oil control ring. Always check the piston ring instruction sheet for the exact procedure.
STEP 5
The piston ring compressor is then put on the piston to hold the rings in their grooves. SEE FIGURES 37–34 AND 37–35.
STEP 6
Rotate the crankshaft so the crankshaft journal is at the bottom (BDC) to help prevent the rod from touching the crankshaft when the piston is installed.
STEP 7
Remove the bearing cap from the rod, and install the bearings.
FIGURE 37–35 This pliers-like tool is used to close the metal band around the piston to compress the rings. An assortment of bands is available to service different size pistons.
STEP 8
Install protectors over the rod bolts. These help prevent damage to the crankshaft journal when the piston/rod assembly is installed. SEE FIGURE 37–36.
STEP 9
The upper rod bearing should be in the rod and the piston should be turned so that the notch on the piston head is facing the front of the engine.
STEP 10 The piston and rod assembly is placed in the cylinder through the block deck. The ring compressor must be kept tightly against the block deck as the piston is pushed into the cylinder. The ring compressor holds the rings in their grooves so that they will enter the cylinder. SEE FIGURE 37–37. STEP 11 The piston is pushed into the cylinder until the rod bearing is fully seated on the journal.
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FIGURE 37–36 When threaded onto the rod bolts, these guides not only help align the rod but also protect the threads and holds the bearing shell in place. The soft ends also will not damage the crankshaft journals.
FIGURE 37–38 The connecting rod side clearance is measured with a feeler gauge.
TECH TIP Tightening Tip for Rod Bearings Even though the bearing clearances are checked, it is still a good idea to check and record the torque required to rotate the crankshaft with all piston rings dragging on the cylinder walls. The retaining nuts on one bearing should be torqued, and then the torque that is required to rotate the crankshaft should be rechecked and recorded. Follow the same procedure on all rod bearings. If tightening any one of the rod bearing caps causes a large increase in the torque required to rotate the crankshaft, immediately stop the tightening process. Determine the cause of the increased rotating torque using the same method as used on the main bearings. Rotate the crankshaft for several revolutions to ensure that the assembly is turning freely and that there are no tight spots. The rotating torque of the crankshaft with all connecting rod cap bolts fully torqued should be as follows: • 4-cylinder engine: 20 lb-ft maximum (88 N-m) • 6-cylinder engine: 25 lb-ft maximum (110 N-m) • 8-cylinder engine: 30 lb-ft maximum (132 N-m)
FIGURE 37–37 Installing a piston using a ring compressor to hold the rings into the ring grooves of the piston and then using a hammer handle to drive the piston into the bore. Connecting rod bolt protectors have been installed to help prevent possible damage to the crankshaft during piston installation.
CONNECTING ROD SIDE CLEARANCE
The connecting rods should be checked to ensure that they still have the correct side clearance. This is measured by fitting the correct thickness of feeler gauge between the connecting rod and the crankshaft cheek of the bearing journal. SEE FIGURE 37–38.
If the side clearance is too great, excessive amounts of oil may escape that can cause lower-than-normal oil pressure. To correct excessive clearance: 1. Weld and regrind or replace the crankshaft. 2. Carefully measure all connecting rods and replace those that are too thin or mismatched.
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If the side clearance is too small, there may not be enough room for heat expansion. To correct a side clearance that is too small: 1. Regrind the crankshaft. 2. Replace the rods.
CYLINDER HEAD INSTALLATION INSTALLING THE CAMSHAFT FOR OHC ENGINES On some overhead camshaft engines, the camshaft is installed before the head is fastened to the block deck. Some engines have the
ADJUSTING SCREW
CAMSHAFT
SPECIAL TOOL USED TO COMPRESS VALVE SPRING
VALVE CLEARANCE
VALVE STEM (a)
CAM LOBE HEEL
ADJUSTING SHIM
MAGNETIC FINGER USED TO REMOVE ADJUSTING SHIM
VALVE CLEARANCE
VALVE LASH ADJUSTING SHIM
CAM FOLLOWER
(b)
FIGURE 37–39 Valve clearance allows the metal parts to expand and maintain proper operation, both when the engine is cold and at normal operating temperature. (a) Adjustment is achieved by turning the adjusting screw. (b) Adjustment is achieved by changing the thickness of the adjusting shim.
camshaft located directly over the valves. The cam bearings on these engines can be either one piece or split. In other engine types, the camshaft bearings are split to allow the camshaft to be installed without the valves being depressed. The cam bearings and journals are lubricated before assembly. The cam bearing caps must be tightened evenly to avoid bending the camshaft. The valve clearance or lash is checked with the overhead camshaft in place. Some engines use shims under a follower disk, as shown in FIGURE 37–39. On these engine types, the camshaft is turned so that the follower is on the base circle of the cam. The clearance of each bucket follower can then be checked with a feeler gauge. The amount of clearance is recorded and compared with the specified clearance, and then a shim of the required thickness is put in the top of the bucket followers, as shown in FIGURE 37–40. Always follow the vehicle manufacturer’s recommended procedures.
HEAD BOLT TORQUE SEQUENCE
The torque put on the bolts is used to control the clamping force that is applied to the gasket. The clamping force is correct only when the threads are clean and properly lubricated. CAUTION: Always use the specified lubricant on the threads. If SAE 30 engine oil is specified, do not use SAE 10W-30 or any other viscosity, because using the incorrect viscosity oil can affect the clamping force exerted on the head gaskets.
In general, the head bolts are tightened in a specified torque sequence in three steps. The procedure starts with the head bolts in the center and then moves to those farther and farther from the center. This procedure helps spread the forces toward the ends of the cylinder.
FIGURE 37–40 Some overhead camshaft engines use valve lash adjusting shims to adjust the valve lash. A special tool is usually required to compress the valve spring so that a magnet can remove the shim. TECH TIP Watch Out for Wet and Dry Holes Many engines, such as the small block Chevrolet V-8, use head bolts that extend through the top deck of the block and end in a coolant passage. These bolt holes are called wet holes. When installing head bolts into holes that end up in the coolant passage, always use sealer on the threads of the head bolt. Some engines have head bolts that are “wet,” whereas others are “dry” because they end in solid cast-iron material. Dry hole bolts do not require sealant, but they still require some oil on the threads of the bolts for lubrication. Do not put oil into a dry hole because the bolt may bottom out in the oil. The liquid oil cannot compress, so the force of the bolt being tightened is transferred to the block by hydraulic force, which can crack the block. HINT: Apply oil to a shop cloth and rotate the bolt in the cloth to lubricate the threads. This procedure lubricates the threads without applying too much oil.
By tightening the head bolts in three steps, the head gasket has time to compress and conform to the block deck and cylinder head gasket surfaces. Follow that sequence and tighten the bolts in the following manner. 1. Tighten to one-third the specified torque. 2. Tighten them a second time following the torque sequence to two-thirds the specified torque.
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3. Follow the sequence with a final tightening to the specified torque. SEE FIGURES 37–41 AND 37–42.
CLAMPING FORCE
Clamping force is the amount of force exerted on a gasket. The clamping force is not the same as the torque applied to the fastener. When tightening a bolt or nut, about 80% of the applied torque is used to overcome friction between the threads. Therefore, it is very important that the threads be clean and lubricated with the proper (specified) lubricant.
FASTENER CONSIDERATION Because most of the torque applied to a fastener is absorbed by friction, it is extremely important that the following steps be performed. STEP 1
Clean the threads of all fasteners before using.
STEP 2
Check service information for the specified thread lubricant.
THREAD LUBRICANT
If using aftermarket bolts or studs, such as ARP (American Racing Products®), use the lubricant and torque that the company specifies. Do not use ARP lubricant and the factory torque specifications or the fasteners will be greatly overtightened. The same applies if using thread sealant to the threads of fasteners being installed in wet holes (holes that extend into the cooling passages). Many vehicle manufacturers recommend the use of 30 weight engine oil (SAE 30).
TECH TIP The Piece of Paper Demonstration Some students and beginning technicians forget the correct order to tighten head bolts or other fasteners of a component. Try the following demonstration: • Place a single sheet of paper on a table. • Place both hands on the paper in the center and then move your hands outward. • Nothing should have happened and the paper should have not moved. • Now place your hands on the paper at the ends and move them toward the center. • The paper will wrinkle as the hands move toward the center. This demonstration shows that the forces are moved away toward the ends the cylinder head if the fasteners are tightened from the inside toward the outside. However, if the cylinder head bolts were tightened incorrectly, the head would likely crack due to the forces exerted during the tightening.
CAUTION: SAE 5W-30 or SAE 10W-30 is not the same as SAE 30 engine oil. Multiviscosity oil such as SAE 5W-30 is actually SAE 5W oil with additives to provide the protection of SAE 30 oil when it gets hot. Always use the exact oil specified by the vehicle manufacturer.
TECH TIP Always “Exercise” New Bolts
10
6
2
3
7
9
5
1
4
8
New bolts and studs are manufactured by rolling the threads and heat treating. Due to this operation, the threads usually have some rough areas, which affect the clamping force on the gasket. Many engine building experts recommend that all new bolts be installed in the engine using a new or used gasket and torqued to specifications at least five times, except for torque-to-yield bolts. This process burnishes the ramps of the threads and makes the fastener provide a more even clamping force. Using the recommended lubricant, the bolts should be torqued and removed and then torqued again.
FIGURE 37–41 Typical cylinder head tightening sequence.
17
15 14
19 11
9
3
1
5
7
13
12
8
6
2
4
10
14
13
9
11 3
5
7
8 1
12
10 2
4
6
14 20 14 18
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13
1 9
11
2 8
4 10
6 12
16
10
6
1
3
7
10
6
2
3
7
8
4
2
5
9
9
5
1
4
8
FIGURE 37–42 Examples of cylinder head bolt torquing sequences.
402
3
5
7
CLAMPING LOAD
INITIAL TORQUE
90° 180°
BOLT TORQUE TORQUE-TO-YIELD
FIGURE 37–43 Typical head gasket markings. The front means that the gasket should be at the accessory drive belt end of the block.
?
FREQUENTLY ASKED QUESTION
FIGURE 37–44 Due to variations in clamping force with turning force (torque) of head bolts, some engines are specifying the torque-to-yield procedure. The first step is to torque the bolts by an even amount called the initial torque. Final clamping load is achieved by turning the bolt a specified number of degrees. Bolt stretch provides the proper clamping force.
Why Do Both Head Gaskets Have “Front” Marked? TORQUE VS. CLAMP LOAD LOW FRICTION (BOLTS CLEAN AND OILED) 12,000 LBS DIFFERENCE
CLAMP LOAD
A common question asked by beginning technicians or students include how to install head gaskets on a V-6 engine that is mounted transversely (sideways) in the vehicle. The technician usually notices that “front” is marked on one gasket and therefore installs that gasket on the block, on top of the forward-facing cylinder bank. Then, the technician notices that the other gasket is also marked with “front.” How could both be marked “front”? There must be some mistake. The mistake is in the terminology used. In the case of head gaskets, the “front” means toward the accessory drive belt end of the engine and not on the cylinder bank toward the front of the vehicle. SEE FIGURE 37–43.
HIGH FRICTION (DIRTY THREADS)
BOLT TORQUE ANGLE OF ROTATION VS. CLAMP LOAD
DEFINITION AND TERMINOLOGY
Many engines use a tightening procedure called the torque-to-yield (TTY) method. The purpose of the TTY procedure is to have a more constant clamping load from bolt to bolt. This aids in head gasket sealing performance and eliminates the need for retorquing.
LOW FRICTION (BOLTS CLEAN AND OILED)
CLAMP LOAD
TORQUE-TO-YIELD HEAD BOLTS
3,000 LBS DIFFERENCE
START OF ANGLE ROTATION
HIGH FRICTION (DIRTY THREADS)
0°
20°
40°
60°
80° 100°
BOLT TORQUE
BOLT CONSTRUCTION Many torque-to-yield head bolts are made with a narrow section between the head and threads. As the bolts are tightened past their elastic limit, they yield and begin to stretch in this narrow section. Torque-to-yield head bolts will not become any tighter once they reach this elastic limit, as seen on the graph in FIGURE 37–44. The torque angle method also decreases the differences in clamping force that can occur depending on the condition or lubrication of the threads. SEE FIGURE 37–45. As a result, many engine manufacturers specify new head bolts each time the head is installed. If these bolts are reused, they are likely to break during assembly or fail prematurely as the engine runs. If there is any doubt about the head bolts, replace them. TORQUE-TO-YIELD PROCEDURE
Torque-to-yield bolts are tightened to a specific initial torque, from 18 to 50 lb-ft (25 to
FIGURE 37–45 To ensure consistent clamp force (load), many manufacturers are recommending the torque-angle or torque-to-yield method of tightening head bolts. The torque-angle method specifies tightening fasteners to a low-torque setting and then giving an additional angle of rotation. Notice that the difference in clamping force is much smaller than it would be if just a torque wrench with dirty threads were used. 68 N-m). The bolts are then tightened an additional specified number of degrees, following the tightening sequence. In some cases they are turned a specified number of degrees two or three times. Some specifications limit the maximum torque that can be applied to the bolt while the degree turn is being made. Torque tables in a service manual will show how much initial torque should be applied to the bolt and how many degrees the bolt should be rotated after torquing. Torque-to-yield head bolts should be tightened as per specified in service information.
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FIGURE 37–46 Torque angle can be measured using a special adaptor. TECH TIP Creep Up on the Torque Value Do not jerk or rapidly rotate a torque wrench. For best results and more even torque, slowly apply force to the torque wrench until it reaches the preset value or the designated torque. Jerky or rapidly moving the torque wrench will often cause the torque to be uneven and not accurate.
The procedure includes the following steps. STEP 1
Tighten the fasteners to an initial torque in the specified sequence.
STEP 2
Turn the fasteners a specific number of degrees using an angle gauge again following the same sequence.
Turn the fasteners another specific number of degrees again following the designated sequence. For example, a specified head bolt tightening specification may include:
FIGURE 37–47 An electronic torque wrench showing the number of degrees of rotation. These very accurate and expensive torque wrenches can be programmed to display torque or number of degrees of rotation.
CAMSHAFT SPROCKET WATER PUMP PULLEY
TENSIONER
TENSION SIDE
STEP 3
Initial torque, such as 44 lb-ft
Rotate 90 degrees
Rotate head bolts an additional 90 degrees
CRANKSHAFT SPROCKET
FIGURE 37–48 Both crankshafts have to be timed on this engine and the timing belt also drives the water pump.
SEE FIGURES 37–46 AND 37–47. PUNCH MARK
PLATED LINK
PUNCH MARK
PUNCH MARK
TORQUE ANGLE METHOD
The torque angle method, also called the torque-turn method, does not necessarily mean torqueto-yield. Some engine specifications call for a beginning torque and then a specified angle, but the fastener is not designed to yield. These head bolts can often be reused. Always follow the manufacturer’s recommended procedures.
VALVE TRAIN ASSEMBLY TIMING DRIVES FOR OHC ENGINES After the head bolts have been torqued, the cam drive can be installed on overhead cam (OHC) engines. This is done by aligning the timing marks of the crankshaft and camshaft drive sprockets with their respective timing marks. The location of these marks differs between engines, but the marks can be identified by looking carefully at the sprockets. SEE FIGURES 37–48 AND 37–49.
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FIGURE 37–49 Some timing chains have plated links that are used to correctly position the chain on the sprockets.
TECH TIP Soak the Timing Chain Many experts recommend that a new timing chain be soaked in engine oil prior to engine assembly to help ensure full lubrication at engine start-up. The timing chain is one of the last places in the engine to get lubrication when the engine first starts. This procedure may even extend the life of the chain.
The tensioner may be on either or both sides of the timing belt or chain. After the camshaft drive is engaged, rotate the crankshaft through two full revolutions. On the first full revolution, the exhaust valve will be almost closed and the intake valve will just be starting to open when the crankshaft timing mark aligns. At the end of the second revolution, both valves should be closed, and all the timing marks should align on most engines. This is the position the crankshaft should have when cylinder 1 is to fire. NOTE: Always check the manufacturer’s recommended timing chain installation procedure. Engines that use primary and secondary timing chains often require an exact detailed procedure for proper installation.
BLEED HOLES FROM HYDRAULIC LASH ADJUSTERS (HLA)
FIGURE 37–50 A special tool may be needed to bleed air from the hydraulic lash adjusters (HLA) through the bleed hole. These lash adjusters are part of the valve end of the rocker arms in this example.
HYDRAULIC VALVE LIFTER INSTALLATION
Most vehicle manufacturers recommend installing lifters without filling or pumping the lifter full of oil. If the lifter is filled with oil during engine start-up, the lifter may not be able to bleed down quickly enough and the valves may be kept open. Not only will the engine not operate correctly with the valves held open, but the piston also could hit the open valves, causing serious engine damage. Most manufacturers usually specify that the lifter be lubricated. Roller hydraulic lifters can be lubricated with engine oil, whereas flat lifters require that engine assembly lube or extreme pressure (EP) grease be applied to the base.
BLEEDING HYDRAULIC LIFTERS Air trapped inside a hydraulic valve lifter can be easily bled by simply operating the engine at a fast idle (2500 RPM). Normal oil flow through the lifters will allow all of the air inside the lifter to be bled out. NOTE: Some engines, such as many Nissan overhead camshaft engines, must have the air removed from the lifter before installation. This is accomplished by submerging the lifter in a container of engine oil and using a straightened paper clip to depress the oil passage check ball. Check service information if in doubt about the bleeding procedure for the vehicle being serviced. SEE FIGURE 37–50.
TIMING MARK ON CAMSHAFT SPROCKET
TIMING CHAINS AND GEARS INSTALLATION
On camin-block (OHV) engines, the timing gears or chain and sprocket can be installed after the crankshaft and camshaft. The timing marks should be aligned according to the factory specified marks. SEE FIGURE 37–51. When used, the replaceable fuel pump eccentric is installed as the cam sprocket is fastened to the cam. The crankshaft should be rotated several times to see that the camshaft and timing gears or chain rotate freely. The timing mark alignment should be rechecked at this time. If the engine is equipped with a slinger ring, it should also be installed on the crankshaft, in front of the crankshaft gear.
OHV ENGINE LIFTER AND PUSHROD INSTALLATION The outside of the lifters and the lifter bores in the block should be
TIMING MARK ON CRANKSHAFT SPROCKET
FIGURE 37–51 Timing chain and gears can be installed after the crankshaft and camshaft have been installed and the timing marks are aligned with cylinder 1 at top dead center (TDC). cleaned and coated with assembly lubricant. The lifters are installed in the lifter bores and the pushrods put in place. There are different length pushrods on some engines. Make sure that the pushrods
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FIGURE 37–52 With the lifter resting on the base circle of the cam, zero lash is achieved by tightening the rocker arm lock nut until the pushrod no longer rotates freely.
FIGURE 37–53 Most adjustable valves use a nut to keep the adjustment from changing. Therefore, to adjust the valves, the nut has to be loosened and the screw rotated until the proper valve clearance is achieved. Then the screw should be held while tightening the lock nut to keep the adjustment from changing. Doublecheck the valve clearance after tightening the nut.
STEP 3 TECH TIP
HINT: This method usually results in about three threads showing above the adjusting nut on a stock small block Chevrolet V-8 equipped with flat-bottom hydraulic lifters.
Watch Out for Different Length Pushrods The very popular General Motors family of engines, including 2.8 liter, 3.1 liter, 3100, 3.4 liter, 3400, and 3.5 liter, each use different pushrod lengths for intake and exhaust valves. If the wrong pushrods are used, two things can occur. 1. The pushrod(s) can be bent. 2. The engine will run rough because the longer pushrod prevents the valve from closing all the way. Always check service information for the exact location of the pushrods.
are installed in the proper location. The rocker arms are then put in place, aligning with the valves and pushrods. Rocker arm shafts should have their retaining bolts tightened a little at a time, alternating between the retaining bolts. This keeps the shaft from bending as the rocker arm pushes some of the valves open.
HYDRAULIC LIFTER ADJUSTMENT
The retaining nut on some rocker arms mounted on studs can be tightened to a specified torque. The rocker arm stud will have a shoulder on this type of rocker assembly. The rocker arm will be adjusted correctly at this torque when the valve tip has the correct height. Other types of rocker arms require tightening the nut to a position that will center the hydraulic lifter. The general procedure includes the following steps. STEP 1
Rotate the engine until cylinder 1 is at TDC on the compression stroke to be assured that both the intake and exhaust valves are on the base circle of the cam lobes.
STEP 2
Tighten the retaining nut to the point that all free lash is gone and the pushrod cannot be easily rotated. SEE FIGURE 37–52.
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From this point, the retaining nut is tightened by a specified amount, such as three-fourths of a turn or one and one-half turns.
STEP 4
Rotate the engine until the next cylinder in the firing order is at top dead center on the compression stroke. The valves on this next cylinder are adjusted in the same manner as those on cylinder 1. This procedure is repeated on each cylinder following the engine firing order until all the valves have been adjusted. Always follow the specified procedure found in service information.
SOLID LIFTER ADJUSTMENT The valve clearance or lash must be set on a solid lifter engine, so that the valves can positively seat. Check service information for the specified adjustment sequence to follow to set the lash. If this is not available, then the following procedure can be used on all engines requiring valve lash adjustment. The valve lash is adjusted with the valves completely closed. SEE FIGURE 37–53. The procedure is similar to that used to adjust hydraulic lifters that are adjustable except that a feeler gauge is used to check the lash. The same valve lash adjustment sequence is used on overhead cam engines. Those engines with rocker arms or with adjustable finger follower pivots are adjusted in the same way as pushrod engines with rocker arms.
FINAL ASSEMBLY MANIFOLD INSTALLATION The intake manifold gasket for a V-type engine may be a one-piece gasket or it may have several pieces. V-type engines with open-type manifolds have a cover over the lifter valley. The cover may be a separate part or it may be part
INTAKE MANIFOLD GASKET
END SEAL
END SEAL
FIGURE 37–54 This intake manifold gasket includes end seals and a full shield cover for the valley to keep hot engine oil from heating the intake manifold.
EXHAUST MANIFOLD GASKETS
EXHAUST PIPE SEAL
FIGURE 37–55 An exhaust manifold gasket is used on some engines. It seals the exhaust manifold to the cylinder head. of a one-piece intake manifold gasket. Closed-type intake manifolds on V-type engines require gasket pieces (end seals) at the front and rear of the intake manifold. SEE FIGURE 37–54. Inline engines usually have a one-piece intake manifold gasket. The intake manifold is put in place over the gaskets. Use a contact adhesive to hold the gasket and end seal if there is a chance they might slip out of place. Install the bolts and tighten to the specified torque following the correct tightening sequence. Only some exhaust manifolds use gaskets. The exhaust manifold operates at very high temperatures, so there is usually some expansion and contraction movement in the manifold-to-head joint. It is very important to use attachment bolts, cap screws, and clamps of the correct type and length. SEE FIGURE 37–55. They must be properly torqued to avoid both leakage and cracks. NOTE: If the exhaust manifold gasket has a metal facing on one side, place the metal facing toward the head.
TIMING COVER INSTALLATION The timing cover with seal installed and gasket are placed over the timing gears and/or chain and sprockets. The attaching bolts are loosely installed to allow the damper hub to align with the cover as it fits in the seal. The damper is installed on the crankshaft. On some engines, it is a press-fit and on others it is held with a large center bolt. After the damper is secured, the attaching bolts on the timing cover can be tightened to the specified torque.
FIGURE 37–56 A 1/8 to 3/16 in. (3 to 5 mm) bead of RTV silicon on a parting surface with silicon going around the bolt hole. Most timing covers are installed with a gasket, but some use RTV sealer in place of the gasket. A bead of RTV silicon 1/8 to 3/16 in. in diameter is put on the clean sealing surface. SEE FIGURE 37–56. Sealing a cover using RTV silicon usually includes the following steps. STEP 1
Encircle the bolt holes with the sealant.
STEP 2
Install the cover before the silicon begins to cure so that the uncured silicon bonds to both surfaces.
STEP 3
While installing the cover, do not touch the silicon bead, otherwise the bead might be displaced and cause a leak.
STEP 4
Carefully press the cover into place. Do not slide the cover after it is in place.
STEP 5
Install the assembly bolts finger tight, and let the silicon cure for about 30 minutes before tightening the cover bolts. When installing cast covers, anaerobic compound (such as Loctite®) is often used as a gasket substitute.
VIBRATION DAMPER INSTALLATION
Vibration dampers
are seated in place by one of three methods.
The damper hub of some engines is pulled into place using the hub attaching bolt.
The second method uses a special installation tool that screws into the attaching bolt hole to pull the hub into place. The tool is removed and the attaching bolt is installed and torqued.
The last method is used on engines that have no attaching bolt. These hubs depend on a press-fit to hold the hub on the crankshaft. The hub is seated using a special tube-type driver. Check service information for the exact procedure and tool to use.
OIL PUMP INSTALLATION
When an engine is rebuilt, the oil pump should be replaced with a new pump and oil pickup screen. Most vehicle manufacturers recommend that the oil pump and screen be replaced rather than cleaned. This ensures positive lubrication and long pump life. Oil pump gears should be coated with assembly lubricant before the cover is put on the pump. This provides initial lubrication, and it primes the pump so that it will draw the oil from the pan when the lubrication system is first operated. Torque the oil pump fasteners to factory specifications. SEE FIGURE 37–57.
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1 MODELING CLAY
PLASTIC WRAP OVER PICKUP SCREEN OIL PUMP PICKUP
FIGURE 37–57 A beam-type torque wrench being used to tighten the oil pump pickup assembly to factory specification.
FIGURE 37–58 Using clay to determine the oil pan to oil pickup clearance, which should be about 1/4 in.
TECH TIP Check the Oil Pump Pickup to Oil Pan Clearance Whenever installing the oil pan on a rebuilt engine, it is wise to check the clearance between the oil pump pickup and the bottom of the oil pan. This distance should be 3/16 to 3/8 in. (5 to 9 mm). To check the clearance, two methods can be used. METHOD 1
With the engine upside down and the oil pump and pickup installed, measure the distance from the oil pan rail to the top (actually the bottom) of the oil pump pickup. Then measure the distance from the oil pan rail to the bottom of the oil pan and subtract the two measurements to get the clearance.
METHOD 2
Place about 1/2 in. (13 mm) of modeling clay on the pickup of the oil pump. Then temporarily install the oil pan with a gasket. Press down on the oil pan to compress the modeling clay. Remove the oil pan and measure the thickness of the clay. This thickness is the oil pan to oil pump pickup clearance. SEE FIGURE 37–58.
FIGURE 37–59 Using a hammer to straighten the gasket rail surface of the oil pan before installing a new gasket. When the retaining bolts are tightened, some distortion of sheet metal covers occurs. If the area around the bolt holes is not straightened, leaks can occur with the new gasket.
REAL WORLD FIX The New Oil Pump That Failed
OIL PAN INSTALLATION
The oil pan should be checked and straightened as necessary. SEE FIGURE 37–59. With the oil pump in place, the oil pan gaskets are properly positioned. The oil pan is carefully placed over the gaskets. All oil pan bolts should be started into their holes before any are tightened. The bolts should be alternately snugged up and then they should be properly tightened to factory specifications. Always follow the instructions that come with the gasket for best results.
WATER PUMP INSTALLATION
A reconditioned, rebuilt, or new water pump should be used. Once gaskets are fitted in place, the pump is secured with assembly bolts tightened to the correct torque.
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A technician replaced the oil pump and screen on a V-8 with low oil pressure. After the repair, the oil pressure returned to normal for two weeks, but then the oil pressure light came on and the valve train started making noise. The vehicle owner returned to the service garage where the oil pump had been replaced. The technician removed the oil pan and pump. The screen was almost completely clogged with the RTV sealant that the technician had used to “seal” the oil pan gasket. The technician had failed to read the instructions that came with the oil pan gasket. Failure to follow directions, and using too much of the wrong sealer, cost the repair shop an expensive comeback repair.
REAL WORLD FIX “Oops”
FIGURE 37–60 Oil should be seen flowing to each rocker arm as shown.
A new thermostat should be installed being careful to check that the wax pellet side of the thermostat faces toward the engine. The thermostat housing with the proper gasket is installed, and the retaining bolts are tightened to the proper torque.
ENGINE PAINTING Painting an engine helps prevent rust and corrosion and makes the engine look new. Standard engine paints with original colors are usually available at automotive parts stores. Engine paints should be used rather than other types of paints. Engine paints are compounded to stay on the metal as the engine temperatures change. Normal engine fluids will not dissolve or remove them. These paints are usually purchased in pressure cans so that they can be sprayed from the can directly onto the engine. All parts that should not be painted must be covered before spray painting. This can be done with old parts, such as old spark plugs and old gaskets. This can also be done by taping paper over the areas to be covered. If the intake manifold of an inline engine is to be painted, it can be painted separately. Engine assembly can continue after the paint has dried. PRELUBRICATING THE ENGINE With oil in the engine and the distributor, if equipped, out of the engine, oil pressure should be established before the engine is started. This can be done on most engines by rotating the oil pump using an electric drive. This ensures that oil is delivered to all parts of the engine before the engine is started. Adapters are available that allow an electric drill motor to rotate the oil pump. Engines that do not drive the oil pump with the distributor will have to be cranked with the spark plugs removed to establish oil pressure. The load on the starter and battery is reduced with the spark plugs out so that the engine will have a higher cranking speed. Rotate the engine as the oil pump is being turned and then look for oil being delivered to each rocker arm which ensures that all of the oil passages are clear. SEE FIGURE 37–60. SETTING IGNITION TIMING After oil pressure is established, the distributor, if equipped, can be installed. Rotate the crankshaft in its normal direction of rotation until there is compression on cylinder 1. This can be done with the starter or by using a wrench on the damper bolt. The compression stroke can be determined by
After overhauling a big block Ford V-8 engine, the technician used an electric drill to rotate the oil pump with a pressure gauge connected to the oil pressure sending unit hole. When the electric drill was turned on, oil pressure would start to increase (to about 10 PSI), then drop to zero. In addition, the oil was very aerated (full of air). Replacing the oil pump did not solve the problem. After hours of troubleshooting and disassembly, it was discovered that an oil gallery plug had been left out underneath the intake manifold. The oil pump was working correctly and pumped oil throughout the engine and out of the end of the unplugged oil gallery. It did not take long for the oil pan to empty and the oil pump began drawing in air that aerated the oil which caused the oil pressure to drop. Installing the gallery plug solved the problem. It was smart of the technician to check the oil pressure before starting the engine. This oversight of leaving out one gallery plug could have resulted in a ruined engine shortly after the engine was started. NOTE: Many overhead camshaft engines use an oil passage check valve in the block near the deck. The purpose of this valve is to hold oil in the cylinder head around the camshaft and lifters when the engine is stopped. Failure to reinstall this check valve can cause the valve train to be noisy after engine start-up.
TECH TIP Install Heat Tabs The wise engine builder should install a heat tab to the back of the cylinder head(s). A heat tab uses a special heat-sensitive metal in the center of a mild steel disc. If the temperature of the cylinder head exceeds 250°F (121°C), the center of the tab will melt and flow out indicating that the engine was overheated. SEE FIGURE 37–61.
covering the opening of spark plug 1 with a finger as the crankshaft is rotated. Continue to rotate the crankshaft slowly as compression is felt, until the timing marks on the damper align with the timing indicator on the timing cover. The angle of the distributor gear drive will cause the distributor rotor to turn a few degrees when installed. Before the distributor is installed, the shaft must be positioned to compensate for the gear angle. After installation, the rotor should be pointing to tower 1 of the distributor cap. The distributor position should be close enough to the basic timing position to start the engine. If the distributor holddown clamp is slightly loose, the distributor housing can be adjusted to make the engine run smoothly after the engine has been started.
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FIGURE 37–61 Heat tabs can be purchased from engine supply companies. WATER ABSORPTION UNIT
DYNAMOMETER TESTING
FIGURE 37–62 A dynamometer measures engine torque by applying a resistive force to the engine and measuring the force applied. Water is being used as the resistive load on this dynamometer.
PURPOSES The purposes for using an engine dynamometer after an engine is assembled are varied. The testing: 1. Allows the completed engine to be started and run to operating temperature 2. Permits checking for possible problems or leaks before the engine is installed in a vehicle 3. Allow the piston rings to seat and the engine to be partially broken in before being installed in a vehicle 4. Permits the technician to determine the output of the engine 5. Allows the opportunity to maximize the engine output by changing air-fuel ratios and valve or ignition timing until the best performance has been achieved
TYPES OF DYNAMOMETERS
Basic types of dynamometers
include:
A brake type, where a variable load is applied to the engine and the computer calculates the power output based on the readings taken from the load cell or strain gauge and engine RPM. Most brake types use a water impeller to create the load on the engine. SEE FIGURE 37–62. An inertia type, which measures engine power by using the engine to accelerate a known mass load. An inertia type dynamometer is most often used to measure the power of an engine at the drive wheels of the vehicle. SEE FIGURE 37–63.
FIGURE 37–63 A chassis dynamometer is used to measure torque at the drive wheels. There is a power loss through the drive train so the measured values are about 20% less than when measuring engine output at the flywheel using an engine dynamometer.
MEASURED VALUES Measured units are those that are obtained directly from sensors and include:
TERMINOLOGY Numbers allow values to be assigned to virtually everything being measured or tested. The numbers help identify, quantify, and compare variables and performance. Two types of data include: 1. Measured values. Taken directly from the engine using sensors that read the actual data 2. Calculated values. Those found by using basic numbers and a formula to obtain them
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Torque. As the name implies, this is the amount of twisting force that the engine puts out at the crank flange. Typically this is measured in foot-pounds. NOTE: Dynamometers only measure torque output of an engine. Horsepower is not measured directly but is instead a calculated value.
Fuel flow. Mass flow rate of fuel is calculated by the number of gallons per hour times pounds per gallon and is measured in pounds per hour. To determine this value, the specific
gravity of the fuel has to be measured and entered into the computer prior to the engine tests so the program can calculate the fuel flow. Make sure there is enough fuel delivery for the engine by checking the gallons per hour prior to running each engine. Proper pressure (PSI) does not mean that there is enough volume being delivered to the engine especially under load conditions.
Manifold pressure. Measured in inches of mercury (in. Hg), this value is called manifold vacuum in a normally aspirated engine.
Oil pressure. This should be about 10 PSI per 1000 RPM.
Air inlet pressure. Core value used to calculate the correction factor during the run, also referred to as dry bulb (DB) temperature. Dry bulb temperature is the temperature of a room where the thermometer is shielded from moisture. This reduces the effect of evaporation of moisture from the thermometer which could affect the temperature reading.
Fuel temperature. Used to calculate the density of fuel for fuel flow values.
Oil temperature. Very important in run-to-run comparisons. Typically, the hotter the oil, the more horsepower an engine makes (up to a point). Oil that is too hot loses its cooling capability as well as some of its lubricating properties.
COIL-ON-PLUG IGNITION COIL
TECH TIP Look at the Crossing Point All dynamometers measure torque of an engine, then calculate the horsepower. Horsepower is torque multiplied by engine speed (RPM) divided by 5,252 (a constant). Therefore, all graphs should show that the two curves for horsepower and torque should be the same at 5,252 RPM. SEE FIGURE 37–65.
Transducers are needed to measure the basic values. A transducer is a device that is able to convert various input signals such as pressures and temperature into an electrical signal that a computer can recognize. Typical dynamometer transducers include: Magnetic pickups SEE FIGURE 37–64.
Load cells
Strain gauge flow meters
Rotary potentiometers or rheostats
Thermocouples
Linear variable displacement transducers (LVDT)
CALCULATED VALUES
Calculated values are those that are obtained by using the measured values and processing them through software to obtain the following:
Corrected torque. This is a calculated number determined by the actual torque multiplied by the correction factor. This is an important number and the reading should show a wide and flat band of torque over a broad engine speed range.
Corrected horsepower. This is a calculated number showing the corrected observed horsepower.
Frictional horsepower. This can best be thought of as the power required to rotate the engine over without firing and without pumping losses.
Volumetric efficiency. This is a measure of the engine’s cylinder filling efficiency; 100% represents filling a cylinder to its total swept volume. On a race engine, it is quite normal to see over 100% volumetric efficiency.
Mechanical efficiency. This is the ratio of the engine’s frictional torque divided by its corrected output torque. A value of 100% would indicate that the engine had no frictional losses.
MAGNETIC PICKUP
FIGURE 37–64 A magnetic pickup being used to monitor engine speed when the vehicle is being tested on a chassis dynamometer.
Engine coolant temperature. This reading is important to monitor as a safety limit to help prevent possible engine damage if it goes too high.
IGNITION PULSE WIRE
STANDARDS For best results, perform testing on nice days with low relative humidity and high atmospheric pressure. These factors have a huge effect on the amount of air that the engine can “breathe” in which in turn can dramatically affect horsepower readings. Testing on nice days is not always possible, so using corrected data allows the technician to compare test results from day to day and dynamometer to dynamometer. A correction factor is a value that is multiplied to the data values so that engine performance can be compared regardless of weather conditions. Over the years there have been many different correction factors specified by the Society of Automotive Engineers (SAE) including:
SAE J606
SAE J607 (Using this correction factor results in higher numbers than if using other correction factors mainly due to the higher barometric pressure standard used.)
SAE J1349
SAE J1739
There are subtle differences between each of the testing standards. The result after the correction factor has been applied is called corrected torque. From the corrected torque values the other units such as horsepower can then be calculated.
FINAL NOTES
Corrected numbers are to be applied to wide open throttle (WOT) runs only.
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CROSSING POINT MAX. POWER - 170.9
MAX TORQUE - 159.0
175
150
150
125
125
100
100
75
75
50
50 20
25
30
35
40
45
50
55
60
65
70
SAE TORQUE (FT-LBS)
SAE HORSEPOWER
HORSEPOWER CURVE
TORQUE CURVE
175
75
RPM (X1000)
FIGURE 37–65 Because horsepower is calculated from measured torque, the horsepower and torque curves should always cross at exactly 5,252 RPM.
Corrected numbers only apply to normally aspirated engines and are not to be used for turbocharged or supercharged engines. Double-check that the spark timing is set relative to top dead center (TDC). Double-check that the engine has good electrical grounds and adequate voltage. Be sure to have enough good fuel before starting to test an engine. Do not use any gasoline older than 90 days.
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TECH TIP Compare Dyno Results from the Same Dyno Only There are too many variables between dynamometers to allow a fair comparison when testing an engine. If changes are made to the engine, try to use the same dynamometer and use the same correction factors. Using another dynamometer can result in readings that may not be equivalent when testing on the original tester.
PLASTIGAGE
1
Clean the main bearing journal and then place a strip of Plastigage material across the entire width of the journal.
2
Carefully install the main bearing cap with the bearing installed.
3
Torque main bearing cap bolts to factory specifications.
4
Carefully remove the bearing cap and, using the package that contained the Plastigage strips, measure the width of the compressed material. The gauge is calibrated in thousandths of the inch. Repeat for each main bearing.
5
To measure rod bearing oil clearance, start by removing the rod cap.
6
Clean the rod bearing journal and then place a strip of Plastigage across the entire width of the journal.
CONTINUED
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PLASTIGAGE
7
(CONTINUED)
Torque the rod bearing cap nuts to factory specifications.
8
Remove the rod cap and measure the oil clearance using the markings on the Plastigage package. The wider the compressed gauge material, the narrower the bearing oil clearance. Repeat for all rod bearings.
REVIEW QUESTIONS 1. List the items that need to be installed as part of the short block assembly. 2. How is crankshaft end play measured?
3. Why should Teflon seals not be oiled prior to being installed? 4. List the measured and the calculated values as a result of testing an engine on a dynamometer.
CHAPTER QUIZ 1. About how much of the turning torque applied to a head bolt is lost to friction? a. 20% c. 60% b. 40% d. 80% 2. Service information states that SAE 30 engine oil should be used on the threads of the head bolts before installation and torquing. Technician A says that SAE 5W-30 will work. Technician B says that SAE 10W-30 will work. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 3. Technician A says that the torque applied to the head bolts is the same as the clamping force on the gasket. Technician B says that the clamping force is the force actually applied to the surfaces of the gasket. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 4. A coating often used to keep an engine from rusting during assembly is called ______________. a. Engine oil c. Fogging oil b. Assembly lube d. Penetrating oil 5. Head gasket installation is being discussed. Technician A says that the surface finish of the cylinder head or block deck is very important for proper sealing to occur. Technician B says that if “front” is marked on a head gasket, the mark should be installed near the accessory drive belt end of the engine. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
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6. Technician A says that studs should be installed finger tight. Technician B says that studs must be installed using a thread locker such as Loctite®. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 7. What can be used to check that heads are at the correct angle for the intake manifold on a V-type engine? a. Metal rule c. Tape measure b. Angle gauge d. Dial indicator 8. What is true about checking bearing clearance using Plastigage? a. The journal should be clean and oil free b. The cap should be torqued to factory specifications c. The wider the strip means the narrower the oil clearance d. all of the above 9. An engine dynamometer measures ______________. a. Torque b. Horsepower c. Both horsepower and torque d. Fuel economy 10. If the torque and horsepower readings are graphed, where do the curves cross (equal each other)? a. Never b. At peak horsepower which can vary from engine to engine c. At peak torque which can vary from engine to engine d. At 5,252 RPM
chapter
38
ENGINE INSTALLATION AND BREAK-IN
OBJECTIVES: After studying Chapter 38, the reader should be able to: • Prepare for ASE Engine Repair (A1) certification test content area “E” (Fuel, Electrical, Ignition, and Exhaust System Inspection and Service). • List the steps necessary to install and start up a rebuilt engine. • Discuss the importance of torquing all bolts or fasteners that connect accessories to the engine block. • Describe what precautions must be taken to prevent damage to the engine when it is first started. • Explain how to break in a newly rebuilt engine. KEY TERMS: Lugging 419 • Normal operating temperature 418
PREINSTALLATION CHECKLIST NEED FOR A CHECKLIST
Engine installation must be thoroughly checked to ensure that it is in proper condition to give the customer dependable operation for a long time. Using a checklist guarantees that all accessories are correctly reinstalled on the engine.
ENGINE INSTALLATION CHECKLIST
Before installing or starting a new or rebuilt engine in a vehicle, be sure all of the following items have been checked. 1. Be sure the battery is fully charged. 2. Prelube the engine and check for proper oil pressure. 3. Check that all electrical wiring connecters and harnesses are properly installed. SEE FIGURE 38–1. 4. Check that all of the vacuum lines are correctly installed and routed.
FIGURE 38–1 A partially melted electrical connector indicates that excessive current flow was present. The cause of the excessive current should be located and corrected before the engine is started.
5. Check that all fuel lines are properly connected and free from leaks. 6. Make sure all engine fluids are at the proper operating level such as coolant, engine oil, and power steering fluid. 7. Know the ignition timing specification and procedure. 8. Check that fresh fuel is in the fuel tank. 9. Be sure that the radiator has been tested, is free from leaks, and flows correctly. 10. Check that all accessory drive belts are routed and tensioned correctly. CAUTION: Be sure to have a fire extinguisher nearby when the engine is first started.
added. The flywheel is installed on the back of the crankshaft. Often, the attaching bolt holes are unevenly spaced so that the flywheel will fit in only one way to maintain engine balance. The pilot bearing or bushing in the rear of the crankshaft is usually replaced with a new one to minimize the possibility of premature failure of this part. The clutch is installed next and the installation usually includes the following steps. STEP 1
Most experts recommend that a new clutch assembly or, at the least, a new clutch friction disc be installed.
STEP 2
The clutch friction disc must be held in position using an alignment tool (sometimes called a dummy shaft) that is secured in the pilot bearing. This holds the disc in position while the pressure plate is being installed.
STEP 3
The engine bell housing is put on the engine, if it was not installed before. The alignment of this type of bell housing is then checked. SEE FIGURE 38–2.
TRANSMISSION INSTALLATION MANUAL TRANSMISSION INSTALLATION If the engine was removed with the transmission attached, the transmission should be reinstalled on the engine before other accessories are
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AFTER CUTTING HEAD OF BOLT, CUT SLOT FOR SCREWDRIVER IN END WITH HACKSAW
FIGURE 38–3 Headless long bolts can be used to help install a transmission to the engine. ALIGNMENT DOWEL PINS
FIGURE 38–2 Bell housing alignment dowel pins are used to ensure proper alignment between the engine block and the transmission.
TECH TIP The Headless Bolt Trick Sometimes parts do not seem to line up correctly. Try this tip the next time. Cut the head off of extra-long bolts that are of the same diameter and thread as those being used to retain the part, such as a transmission. SEE FIGURE 38–3. Use a hacksaw to cut a slot in this end of the guide bolts for a screwdriver slot. Install the guide bolts; then install the transmission. Use a straight-blade screwdriver to remove the guide bolts after securing the transmission with the retaining bolts.
CAUTION: Perfectly round cylinders can be distorted whenever another part of the engine is bolted and torqued to the engine block. For example, it has been determined that after the cylinders are machined, the rear cylinder bore can be distorted to be as much as 0.006 in. (0.15 mm) out-of-round after the bell housing is bolted onto the block! To help prevent this distortion, always apply the specified torque to all fasteners going into the engine block and tighten in the recommended sequence. STEP 4
STEP 5
416
The clutch release yoke should be checked for free movement. Usually, the clutch release bearing is replaced to ensure that the new bearing is securely attached to the clutch release yoke. The transmission is installed by carefully guiding the transmission input (clutch) shaft straight into the clutch disc and pilot bearing. See the Tech Tip, “The Headless Bolt Trick.” Rotate the transmission output shaft as needed to engage the splines of the clutch disc. The assembly bolts are secured when the transmission fully mates with the bell housing.
CHAPTER 3 8
FRONT SEAL
STATOR SUPPORT SHAFT
INPUT SHAFT
FIGURE 38–4 The internal splines inside the torque converter must be properly aligned with all of the splines of the automatic transmission.
CAUTION: Always adjust the clutch free play before starting the engine to help prevent engine thrust bearing or clutch release bearing damage.
AUTOMATIC TRANSMISSION INSTALLATION On engines equipped with an automatic transmission, the drive (flex) plate is attached to the back of the crankshaft. Its assembly bolts are tightened to the specified torque. The bell housing is part of the transmission case on most automatic transmissions. Installing an automatic transmission usually includes the following steps. STEP 1
The torque converter should be installed on the transmission before the transmission is put on the engine.
STEP 2
Rotate the torque converter while it is pushed onto the transmission shafts until the splines of all shafts are engaged in the torque converter. SEE FIGURE 38–4.
STEP 3
The torque converter is held against the transmission as the transmission is fitted on the back of the engine. The transmission mounting bolts are attached finger tight.
STEP 4
The torque converter should be rotated to make sure that there is no binding. The bell housing is secured to the block and then the torque converter is fastened to the drive plate.
FIGURE 38–5 It is often easier to install all of the accessory drive belts before the engine is installed in the vehicle.
FIGURE 38–6 A fixture installed that is used as a place to attach the hosting chains.
compartment first. The transmission is worked under the floor pan on rear-wheel-drive vehicles as the engine is lowered into the engine compartment. The front engine mounts are aligned and the rear cross-member and rear engine mount are installed. The engine mount bolts are installed, and the nuts are torqued. Then the hoist is removed.
DRESSING THE ENGINE “Dressing the engine” is a term used to describe the process of attaching all of the auxiliary items to the engine. The items include:
Starter motor
Fuel rail and related fuel system components
New oxygen sensor(s), to ensure that the engine will be operating at the correct air-fuel ratio
Engine/transmission wiring harness
Ignition components, such the ignition coil(s) and spark plug wires, if equipped
All belt-driven engine accessories, mounted on the front of the engine (Some engines drive all these accessories with one belt. Other engines use as many as four belts. Check service information or decals under the hood to determine the specific belt routing for the accessories used on the engine.) SEE FIGURE 38–5.
Front accessories, such as the power steering pump, alternator, and air-conditioning compressor (These accessories may be installed before the engine is installed in the vehicle. On some vehicles it is easier to put the engine in the chassis before installing the front accessories.)
Always check service information for the exact procedure to follow.
ENGINE INSTALLATION SECURING THE ENGINE
A sling, either a chain or lift cable, is attached to the manifold or head bolts or lifting brackets on the top of the engine. A hoist is attached to the sling and snugged up to take the weight and to make sure that the engine is supported and balanced properly. SEE FIGURE 38–6.
RECONNECTING COMPONENTS AND CONNECTORS
Rear-wheel drive. The engine must be tipped as it was during removal to let the transmission go into the engine
The
following items should be connected to the engine assembly.
Throttle and cruise control linkages or cables
Exhaust system to the exhaust manifolds
If any of the steering linkage was previously disconnected, it can be reattached while work is being done under the vehicle.
After the engine is in place, the front engine accessories can all be installed, if they were not installed before the engine was put in the chassis.
The air-conditioning compressor is reattached to the engine, with care being taken to avoid damaging the air-conditioning hoses and lines.
COOLING SYSTEM The radiator is installed and secured in place, followed by the cooling fan and shroud. The fan and new drive belts are then installed and adjusted. New radiator hoses, including new heater hoses, and new coolant should be installed. ELECTRICAL SYSTEM Under the hood the following electrical components will need to be mounted and connected.
Connect all wiring to the starter and alternator as required.
Connect the instrument and computer sensor wires to the sensors on the engine.
Double-check the condition and routing of all wiring, being certain that wires have not been pinched or broken, before installing a fully charged battery.
Attach the positive cable first and then the ground cable.
INSTALLING THE ENGINE
Front-wheel drive. Many engines for front-wheel-drive vehicles are installed from underneath the vehicle. Often the entire drivetrain package is placed back in the vehicle while it is attached to the cradle. The vehicle is positioned on a hoist and is lowered onto the engine cradle assembly to install. Always check the recommended procedure for the vehicle being serviced.
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417
?
FREQUENTLY ASKED QUESTION
What Is Break-In Engine Oil? Many years ago, vehicle manufacturers used straight weight such as SAE 30 nondetergent engine oil as break-in oil. Today, the engine oil recommended for break-in (running in) is the same type of oil that is recommended for use in the engine. No special break-in oil is recommended or used by the factory in new vehicles. Always use the specified viscosity oil as recommended by the vehicle manufacturer.
Ensure that the starter will crank the engine.
Install and time the distributor (if equipped), then connect the ignition cables to the spark plugs, again being sure that they are routed according to service information.
ENGINE START PRECAUTIONS
The engine installation should be given one last inspection to ensure that everything has been put together correctly before the engine is started. If the engine overhaul and installation are done properly, the engine should crank and start on its own fully charged battery without the use of a fast charger or jumper battery. As soon as the engine starts and shows oil pressure, it should be brought up to a fast idle speed and kept there to ensure that the engine gets proper lubrication. The fast-running oil pump develops full pressure, and the fastturning crankshaft throws plenty of oil on the cam and cylinder walls. NOTE: In camshaft-in-block engines, the only lubrication sent to the contact point between the camshaft lobes and the lifters (tappets) is from the splash off the crankshaft and connecting rods. At idle, engine oil does not splash enough for proper break-in lubrication of the camshaft. Maintaining engine speed above 1,500 RPM for the first 10 minutes of engine operation must be performed to break in a flat-bottom lifter camshaft. If the engine speed is decreased to idle (about 600 RPM), the lifter (tappet) will be in contact with and exerting force on the lobe of the cam for a longer period of time than occurs at higher engine speeds. The pressure and volume of oil supplied to the camshaft area are also increased at the higher engine speeds. Therefore, to ensure long camshaft and lifter life, make certain that the engine will start quickly after reassembly to prevent long cranking periods and subsequent low engine speeds after a new camshaft and lifters have been installed. NOTE: Many molydisulfide greases used during assembly can start to clog oil filters within 20 minutes after starting the engine. Most engine rebuilders recommend changing the oil and filter after 30 minutes of running time. After the engine has started, the following items should be checked. 1. Is the valve train quiet? Some engines will require several minutes to quiet down. 2. Record the engine vacuum. It should be 17 to 21 in. Hg (sea level). 3. Check for any gasoline, coolant, or oil leaks. Stop the engine and repair the leaks as soon as possible. 4. Check the charging system for proper operation. The charging voltage should be 13.5 to 15 volts.
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FIGURE 38–7 Even though the dash gauge may show normal operating temperature, a scan tool or an infrared pyrometer can also be used to verify proper coolant temperature. As soon the engine is at operating temperature and running well, the vehicle should be driven to a road having minimum traffic. Perform the following during the test drive.
The vehicle should be accelerated, full throttle, from 30 to 50 mph (48 to 80 km/h).
Then the throttle is fully closed while the vehicle is allowed to return to 30 mph (48 km/h). This sequence is repeated 10 to 12 times.
The acceleration sequence puts a high load on the piston rings to properly seat them against the cylinder walls. The piston rings are the only part of the modern engine that needs to be broken in. Good ring seating is indicated by a dry coating inside the tailpipe at the completion of the ring seating drive.
The vehicle is returned to the service area, where the engine is again checked for visible fluid leaks. If the engine is dry, it is ready to be turned over to the customer. The customer should be instructed to drive the vehicle in a normal fashion, neither babying it at slow speeds nor beating it at high speeds for the first 100 miles (160 km). The oil and filter should be changed at 500 miles (800 km) to remove any dirt that may have been trapped in the engine during assembly and to remove the material that has worn from the surfaces during the break-in period. A well-designed engine that has been correctly reconditioned and assembled using the techniques described should give reliable service for many miles.
NORMAL OPERATING TEMPERATURE
Normal operating temperature is the temperature at which the upper radiator hose is hot and pressurized. Another standard method used to determine when normal operating temperature is reached is to observe the operation of the electric cooling fan, when the vehicle is so equipped. Many manufacturers define normal operating temperature as being reached when the cooling fan has cycled on and off at least once after the engine has been started. Some vehicle manufacturers specify that the cooling fan should cycle twice. This method also helps assure the technician that the engine is not being overheated. SEE FIGURE 38–7.
HOW TO WARM UP A COLD ENGINE The greatest amount of engine wear occurs during start-up. The oil in a cold engine is thick, and it requires several seconds to reach all the moving parts of an engine. After the engine starts, allow the engine to idle until the oil pressure peaks. This will take from 15 to 60 seconds, depending on the outside
temperature. Do not allow the engine to idle for longer than five minutes. Because an engine warms up faster under load, drive the vehicle in a normal manner until the engine is fully warm. Avoid full-throttle acceleration until the engine is completely up to normal operating temperature. This method of engine warm-up also warms the rest of the powertrain, including transmission and final drive component lubricants.
BREAK-IN PRECAUTIONS Any engine overhaul represents many hours of work and a large financial investment. Precautions should be taken to protect the investment, including the following: 1. Never add cold water to the cooling system while the engine is running.
2. Never lug any engine. Lugging means increasing the throttle opening without increasing engine speed (RPM). An example where lugging an engine can occur is when the vehicle is driven at a low speed, such as 15 mph, with the manual transmission in third or fourth gear instead of in second gear as per the recommended speed for that gear as published in the owner manual. 3. Applying loads to an engine for short periods of time creates higher piston ring pressure against the cylinder walls and assists the breaking-in process by helping to seat the rings. 4. Change the oil and filter at 500 miles (800 km) or after 20 hours of operation. 5. Check for leaks after the engine has gone through several warm-up and cooling down periods.
REVIEW QUESTIONS 1. How are the clutch and bell housing installed?
3. Describe the engine break-in procedure.
2. What should be done to help prevent rear cylinder distortion when the bell housing is being installed on the engine?
CHAPTER QUIZ 1. “Dressing the engine” means ______________. a. Installing all of the exterior engine components b. Cleaning the engine c. Changing the oil and oil filter d. Both b and c 2. If the bell housing is not properly torqued to the engine block, ______________. a. The bell housing will distort b. The engine block will crack c. The rear cylinder can be distorted (become out-of-round) d. The crankshaft will crack 3. Break-in engine oil is ______________. a. Of the same viscosity and grade as that specified for normal engine operation b. SAE 40 c. SAE 30 d. SAE 20W-50 4. Normal operating temperature is reached when ______________. a. The radiator cap releases coolant into the overflow b. The upper radiator hose is hot and pressurized c. The electric cooling fan has cycled at least once (if the vehicle is so equipped) d. Both b and c 5. Lugging an engine means ______________. a. Wide-open throttle in low gear above 25 mph b. That engine speed does not increase when the throttle is opened wider c. Starting a cold engine and allowing it to idle for longer than five minutes d. Both b and c
6. Which computer sensor should be replaced to help ensure that the engine will be operating at the correct air-fuel ratio? a. Throttle position sensor b. Oxygen sensor c. Manifold absolute pressure sensor d. Engine coolant temperature sensor 7. How should the vehicle be driven to best break in a newly overhauled engine? a. At a steady low speed b. At varying speeds and loads c. At high speed and loads d. At idle speed and little or no load 8. Which type of vehicle is the engine most likely to be installed from underneath the vehicle? a. Rear-wheel drive (RWD) b. Front-wheel drive (FWD) c. Four-wheel drive (4WD) d. Both a and c 9. Engine vacuum on a normal stock rebuilt engine should be ______________. a. 10 to 15 in. Hg b. 12 to 16 in. Hg c. 17 to 21 in. Hg d. 19 to 23 in. Hg 10. Why must flat-bottom camshafts be broken in at a fast idle? a. Cam in a cam-in-block engine is only lubricated by splash oil. b. The flat-bottom of the lifters must become slightly concave in order to rotate. c. Both a and b are correct d. Neither a nor b are correct
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S E C T I O N
VII
Electrical and Electronic Systems
39 Electrical Fundamentals
51 Battery Testing and Service
40 Electrical Circuits and Ohm’s Law
52 Cranking Systems
41 Series, Parallel, and Series-Parallel Circuits
53 Cranking System Diagnosis and Service
42 Circuit Testers and Digital Meters
54 Charging Systems
43 Oscilloscopes and Graphing Multimeters
55 Charging System Diagnosis and Service
44 Automotive Wiring and Wire Repair
56 Lighting and Signaling Circuits
45 Wiring Schematics and Circuit Testing
57 Driver Information and Navigation Systems
46 Capacitance and Capacitors
58 Horn, Wiper, and Blower Motor Circuits
47 Magnetism and Electromagnetism
59 Accessory Circuits
48 Electronic Fundamentals
60 Restraint Systems and Airbags
49 CAN and Network Communications
61 Audio System Operation and Diagnosis
50 Batteries
chapter
ELECTRICAL FUNDAMENTALS
39 OBJECTIVES: After studying Chapter 39, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic System Diagnosis). • Define electricity. • Explain the units of electrical measurement. • Discuss the relationship among volts, amperes, and ohms. • Explain how magnetism is used in automotive applications. KEY TERMS: Ammeter 424 • Ampere 424 • Atom 421 • Bound electrons 422 • Conductors 422 • Conventional theory 424 • Coulomb 424 • Electrical potential 424 • Electricity 421 • Electrochemistry 426 • Electromotive force (EMF) 424 • Electron theory 424 • Free electrons 422 • Insulators 423 • Ion 422 • Neutral charge 421 • Ohmmeter 425 • Ohms 425 • Peltier effect 425 • Photoelectricity 426 • Piezoelectricity 426 • Positive temperature coefficient (PTC) 426 • Potentiometer 427 • Resistance 425 • Rheostat 427 • Semiconductor 423 • Static electricity 425 • Thermocouple 425 • Thermoelectricity 425 • Valence ring 422 • Volt 424 • Voltmeter 425 • Watt 425
INTRODUCTION The electrical system is one of the most important systems in a vehicle today. Every year more and more components and systems use electricity. Those technicians who really know and understand automotive electrical and electronic systems will be in great demand.
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Electricity may be difficult for some people to learn for the following reasons.
It cannot be seen.
Only the results of electricity can be seen.
It has to be detected and measured.
The test results have to be interpreted.
JUPITER EARTH PROTON
POSITIVE MERCURY
SUN
ELECTRON
VENUS MARS
HYDROGEN ATOM
FIGURE 39–1 In an atom (left), electrons orbit protons in the nucleus just as planets orbit the sun in our solar system (right).
ELECTRICITY BACKGROUND
Our universe is composed of matter, which is anything that has mass and occupies space. All matter is made from slightly over 100 individual components called elements. The smallest particle that an element can be broken into and still retain the properties of that element is known as an atom. SEE FIGURE 39–1.
NEGATIVE
FIGURE 39–2 The nucleus of an atom has a positive (⫹) charge and the surrounding electrons have a negative (⫺) charge.
DEFINITION
Electricity is the movement of electrons from one atom to another. The dense center of each atom is called the nucleus. The nucleus contains:
Protons, which have a positive charge
Neutrons, which are electrically neutral (have no charge)
3 1
Electrons, which have a negative charge, surround the nucleus in orbits. Each atom contains an equal number of electrons and protons. The physical aspect of all protons, electrons, and neutrons are the same for all atoms. It is the number of electrons and protons in the atom that determines the material and how electricity is conducted. Because the number of negative-charged electrons is balanced with the same number of positive-charged protons, an atom has a neutral charge (no charge). NOTE: As an example of the relative sizes of the parts of an atom, consider that if an atom were magnified so that the nucleus were the size of the period at the end of this sentence, the whole atom would be bigger than a house.
1
2 3
6 5
4
4 2 5
POSITIVE AND NEGATIVE CHARGES
The parts of the atom have different charges. The orbiting electrons are negatively charged, while the protons are positively charged. Positive charges are indicated by the “plus” sign (⫹), and negative charges by the “minus” sign (⫺), as shown in FIGURE 39–2. These same ⫹ and ⫺ signs are used to identify parts of an electrical circuit. Neutrons have no charge at all. They are neutral. In a normal, or balanced, atom, the number of negative particles equals the number of positive particles. That is, there are as many electrons as there are protons. SEE FIGURE 39–3.
6
FIGURE 39–3 This figure shows a balanced atom. The number of electrons is the same as the number of protons in the nucleus.
N
S N
S
S
N
FIGURE 39–4 Unlike charges attract and like charges repel.
MAGNETS AND ELECTRICAL CHARGES
An ordinary magnet has two ends, or poles. One end is called the south pole, and the other is called the north pole. If two magnets are brought close to each other with like poles together (south to south or north to north), the magnets will push each other apart, because like poles repel each other. If the opposite poles of the magnets are brought close to each other, south to north, the magnets will snap together, because unlike poles attract each other.
The positive and negative charges within an atom are like the north and south poles of a magnet. Charges that are alike will repel each other, similar to the poles of a magnet. SEE FIGURE 39–4. That is why the negative electrons continue to orbit around the positive protons. They are attracted and held by the opposite charge of the protons. The electrons keep moving in orbit because they repel each other.
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421
ORBIT LEVELS
FREE ELECTRONS
+ +
+ +
+ +
FIGURE 39–5 An unbalanced, positively charged atom (ion) will attract electrons from neighboring atoms. VALANCE RING
BOUND ELECTRONS
FIGURE 39–7 As the number of electrons increases, they occupy increasing energy levels that are farther from the center of the atom. PROTON + ELECTRON
NUCLEUS
–
HYDROGEN ATOM (1 ELECTRON)
ALUMINUM ATOM (13 ELECTRONS)
FREE ELECTRON
FIGURE 39–8 Electrons in the outer orbit, or shell, can often be drawn away from the atom and become free electrons. CONDUCTORS COPPER ATOM (29 ELECTRONS)
SILVER ATOM (61 ELECTRONS)
FIGURE 39–6 The hydrogen atom is the simplest atom, with only one proton, one neutron, and one electron. More complex elements contain higher numbers of protons, neutrons, and electrons.
IONS When an atom loses any electrons, it becomes unbalanced. It will have more protons than electrons, and therefore will have a positive charge. If it gains more electrons than protons, the atom will be negatively charged. When an atom is not balanced, it becomes a charged particle called an ion. Ions try to regain their balance of equal protons and electrons by exchanging electrons with neighboring atoms. The flow of electrons during the “equalization” process is defined as the flow of electricity. SEE FIGURE 39–5. ELECTRON SHELLS Electrons orbit around the nucleus in definite paths. These paths form shells, like concentric rings, around the nucleus. Only a specific number of electrons can orbit within each shell. If there are too many electrons for the first and closest shell to the nucleus, the others will orbit in additional shells until all electrons have an orbit within a shell. There can be as many as seven shells around a single nucleus. SEE FIGURE 39–6.
FIGURE 39–9 A conductor is any element that has one to three electrons in its outer orbit. If the valence ring of an atom has three or fewer electrons in it, the ring has room for more. The electrons there are held very loosely, and it is easy for a drifting electron to join the valence ring and push another electron away. These loosely held electrons are called free electrons. When the valence ring has five or more electrons in it, it is fairly full. The electrons are held tightly, and it is hard for a drifting electron to push its way into the valence ring. These tightly held electrons are called bound electrons. SEE FIGURES 39–7 AND 39–8. The movement of these drifting electrons is called current. Current can be small, with only a few electrons moving, or it can be large, with a tremendous number of electrons moving. Electric current is the controlled, directed movement of electrons from atom to atom within a conductor.
CONDUCTORS FREE AND BOUND ELECTRONS
The outermost electron shell or ring, called the valence ring, is the most important part of understanding electricity. The number of electrons in this outer ring determines the valence of the atom, and indicates its capacity to combine with other atoms.
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Conductors are materials with fewer than four electrons in their atom’s outer orbit. SEE FIGURE 39–9. Copper is an excellent conductor because it has only one electron in its outer orbit. This orbit is far enough away from the nucleus of the copper atom that the pull or force holding the outermost electron in orbit is relatively weak. SEE FIGURE 39–10.
COPPER
INSULATORS ELECTRON
FIGURE 39–11 Insulators are elements with five to eight electrons in the outer orbit.
ORBIT
NUCLEUS (29 PROTONS + 35 NEUTRONS)
SEMICONDUCTORS
FIGURE 39–10 Copper is an excellent conductor of electricity because it has just one electron in its outer orbit, making it easy to be knocked out of its orbit and flow to other nearby atoms. This causes electron flow, which is the definition of electricity.
?
FREQUENTLY ASKED QUESTION
FIGURE 39–12 Semiconductor elements contain exactly four electrons in the outer orbit.
Is Water a Conductor? Pure water is an insulator; however, if anything is in the water, such as salt or dirt, then the water becomes conductive. Because it is difficult to keep it from becoming contaminated, water is usually thought of as being capable of conducting electricity, especially high-voltage household 110 or 220 volt outlets.
COPPER WIRE POSITIVE (+) CHARGE
NEGATIVE (-) CHARGE
FIGURE 39–13 Current electricity is the movement of electrons through a conductor.
SEMICONDUCTORS Copper is the conductor most used in vehicles because the price of copper is reasonable compared to the relative cost of other conductors with similar properties. Examples of other commonly used conductors include:
Materials with exactly four electrons in their outer orbit are neither conductors nor insulators, but are called semiconductors. Semiconductors can be either an insulator or a conductor in different design applications. SEE FIGURE 39–12. Examples of semiconductors include:
Silicon
Silver
Germanium
Gold
Carbon
Aluminum
Steel
Cast iron
INSULATORS
Some materials hold their electrons very tightly; therefore, electrons do not move through them very well. These materials are called insulators. Insulators are materials with more than four electrons in their atom’s outer orbit. Because they have more than four electrons in their outer orbit, it becomes easier for these materials to acquire (gain) electrons than to release electrons. SEE FIGURE 39–11. Examples of insulators include:
Rubber
Plastic
Nylon
Porcelain
Ceramic
Fiberglass
Examples of insulators include plastics, wood, glass, rubber, ceramics (spark plugs), and varnish for covering (insulating) copper wires in alternators and starters.
Semiconductors are used mostly in transistors, computers, and other electronic devices.
HOW ELECTRONS MOVE THROUGH A CONDUCTOR CURRENT FLOW The following events occur if a source of power, such as a battery, is connected to the ends of a conductor— a positive charge (lack of electrons) is placed on one end of the conductor and a negative charge (excess of electrons) is placed on the opposite end of the conductor. For current to flow, there must be an imbalance of excess electrons at one end of the circuit and a deficiency of electrons at the opposite end of the circuit.
The negative charge will repel the free electrons from the atoms of the conductor, whereas the positive charge on the opposite end of the conductor will attract electrons.
As a result of this attraction of opposite charges and repulsion of like charges, electrons will flow through the conductor. SEE FIGURE 39–13.
E L E C T RI C AL F U N D A M EN T A L S
423
AMMETER
FLOW OF CURRENT (CONVENTIONAL THEORY)
FIGURE 39–16 An ammeter is installed in the path of the electrons similar to a water meter used to measure the flow of water in gallons per minute. The ammeter displays current flow in amperes.
VOLTAGE
FIGURE 39–14 Conventional theory states that current flows through a circuit from positive (⫹) to negative (⫺). Automotive electricity uses the conventional theory in all electrical diagrams and schematics.
VOLTAGE IS PRESSURE
FIGURE 39–17 Voltage is the electrical pressure that causes the electrons to flow through a conductor.
COPPER WIRE POSITIVE (+) CHARGE
6.28 BILLION BILLION ELECTRONS PER SECOND
NEGATIVE (-) CHARGE
(1 AMPERE)
FIGURE 39–15 One ampere is the movement of 1 coulomb (6.28 billion billion electrons) past a point in 1 second.
CONVENTIONAL THEORY VERSUS ELECTRON THEORY
Conventional theory. It was once thought that electricity had only one charge and moved from positive to negative. This theory of the flow of electricity through a conductor is called the conventional theory of current flow. SEE FIGURE 39–14. Electron theory. The discovery of the electron and its negative charge led to the electron theory, which states that there is electron flow from negative to positive. Most automotive applications use the conventional theory. This book will use the conventional theory (positive to negative) unless stated otherwise.
UNITS OF ELECTRICITY Electricity is measured using meters or other test equipment. The three fundamentals of electricity-related units include the ampere, volt, and ohm.
AMPERES
The ampere is the unit used throughout the world to measure current flow. When 6.28 billion billion electrons (the name for this large number of electrons is a coulomb) move past a certain point in 1 second, this represents 1 ampere of current. SEE FIGURE 39–15. The ampere is the electrical unit for the amount of electron flow, just as “gallons per minute” is the unit that can be used to measure the quantity of water flow. It is named for the French electrician, Andrè Marie Ampére (1775–1836). The conventional abbreviations and measurement for amperes are as follows: 1. The ampere is the unit of measurement for the amount of current flow. 2. A and amps are acceptable abbreviations for amperes.
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3. The capital letter I, for intensity, is used in mathematical calculations to represent amperes. 4. Amperes do the actual work in the circuit. It is the actual movement of the electrons through a light bulb or motor that actually makes the electrical device work. Without amperage through a device it will not work at all. 5. Amperes are measured by an ammeter (not ampmeter). SEE FIGURE 39–16.
VOLTS The volt is the unit of measurement for electrical pressure. It is named for an Italian physicist, Alessandro Volta (1745–1827). The comparable unit using water pressure as an example would be pounds per square inch (psi). It is possible to have very high pressures (volts) and low water flow (amperes). It is also possible to have high water flow (amperes) and low pressures (volts). Voltage is also called electrical potential, because if there is voltage present in a conductor, there is a potential (possibility) for current flow. This electrical pressure is a result of the following:
Excess electrons remain at one end of the wire or circuit.
There is a lack of electrons at the other end of the wire or circuit.
The natural effect is to equalize this imbalance, creating a pressure to allow the movement of electrons through a conductor.
It is possible to have pressure (volts) without any flow (amperes). For example, a fully charged 12 volt battery sitting on a workbench has 12 volts of pressure potential, but because there is not a conductor (circuit) connected between the positive and negative posts of the battery, there is no flow (amperes). Current will only flow when there is pressure and a circuit for the electrons to flow in order to “equalize” to a balanced state.
Voltage does not flow through conductors, but voltage does cause current (in amperes) to flow through conductors. SEE FIGURE 39–17. The conventional abbreviations and measurement for voltage are as follows: 1. The volt is the unit of measurement for the amount of electrical pressure. 2. Electromotive force, abbreviated EMF, is another way of indicating voltage.
FIGURE 39–18 This digital multimeter set to read DC volts is being used to test the voltage of a vehicle battery. Most multimeters can also measure resistance (ohms) and current flow (amperes).
CURRENT
FIGURE 39–20 A display at the Henry Ford Museum in Dearborn, Michigan, which includes a hand-cranked generator and a series of light bulbs. This figure shows a young man attempting to light as many bulbs as possible. The crank gets harder to turn as more bulbs light because it requires more power to produce the necessary watts of electricity.
VOLTAGE
bulb powered by 120 volts AC in the shop requires how many amperes? RESISTANCE
FIGURE 39–19 Resistance to the flow of electrons through a conductor is measured in ohms. 3. V is the generally accepted abbreviation for volts. 4. The symbol used in calculations is E, for electromotive force.
A (amperes) ⫽ P (watts) divided by E (volts) A ⫽ 0.83 amperes
SEE FIGURE 39–20.
SOURCES OF ELECTRICITY
5. Volts are measured by a voltmeter. SEE FIGURE 39–18.
FRICTION
OHMS
Resistance to the flow of current through a conductor is measured in units called ohms, named after the German physicist, George Simon Ohm (1787–1854). The resistance to the flow of free electrons through a conductor results from the countless collisions the electrons cause within the atoms of the conductor. SEE FIGURE 39–19. The conventional abbreviations and measurement for resistance are as follows: 1. The ohm is the unit of measurement for electrical resistance. 2. The symbol for ohms is Ω (Greek capital letter omega), the last letter of the Greek alphabet. 3. The symbol used in calculations is R, for resistance. 4. Ohms are measured by an ohmmeter. 5. Resistance to electron flow depends on the material used as a conductor.
WATTS A watt is the electrical unit for power, the capacity to do work. It is named after a Scottish inventor, James Watt (1736–1819). The symbol for power is P. Electrical power is calculated as amperes times volts: P (power) I (amperes) E (volts) The formula can also be used to calculate the amperage if the wattage and the voltage are known. For example, a 100 watt light
When certain different materials are rubbed together, the friction causes electrons to be transformed from one to the other. Both materials become electrically charged. These charges are not in motion, but stay on the surface where they were deposited. Because the charges are stationary, or static, this type of voltage is called static electricity. Walking across a carpeted floor creates a buildup of a static charge in your body which is an insulator and then the charge is discharged when you touch a metal conductor. Vehicle tires rolling on pavement often create static electricity that interferes with radio reception.
HEAT When pieces of two different metals are joined together at both ends and one junction is heated, current passes through the metals. The current is very small, only millionths of an ampere, but this is enough to use in a temperature-measuring device called a thermocouple. SEE FIGURE 39–21. Some engine temperature sensors operate in this manner. This form of voltage is called thermoelectricity. Thermoelectricity was discovered and has been known for over a century. In 1823, a German physicist, Thomas Johann Seebeck, discovered that a voltage was developed in a loop containing two dissimilar metals, provided the two junctions were maintained at different temperatures. A decade later, a French scientist, Jean Charles Athanase Peltier, found that electrons moving through a solid can carry heat from one side of the material to the other side. This effect is called the Peltier effect. A Peltier effect device is often used in
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–
–
– –
–
– –
– –
+
+
+ +
+
–
–
CRYSTAL –
–
FIGURE 39–21 Electron flow is produced by heating the connection of two different metals.
– –
–
–
– –
FIGURE 39–23 Electron flow is produced by pressure on certain crystals.
–
?
–
– –
LIGHT SOURCE
–
FREQUENTLY ASKED QUESTION
Why Is Gold Used if Copper Has Lower Resistance? Copper is used for most automotive electrical components and wiring because it has low resistance and is reasonably priced. Gold is used in airbag connections and sensors because it does not corrode. Gold can be buried for hundreds of years and when dug up it is just as shiny as ever.
ELECTRON FLOW
SELENIUM ALLOY TRANSLUCENT MATERIAL
– –
IRON
FIGURE 39–22 Electron flow is produced by light striking a light-sensitive material.
portable coolers to keep food items cool if the current flows in one direction and keep items warm if the current flows in reverse.
LIGHT
In 1839, Edmond Becquerel noticed that by shining a beam of sunlight over two different liquids, he could develop an electric current. When certain metals are exposed to light, some of the light energy is transferred to the free electrons of the metal. This excess energy breaks the electrons loose from the surface of the metal. They can then be collected and made to flow in a conductor. SEE FIGURE 39–22. This photoelectricity is widely used in light-measuring devices such as photographic exposure meters and automatic headlamp dimmers.
PRESSURE The first experimental demonstration of a connection between the generation of a voltage due to pressure applied to a crystal was published in 1880 by Pierre and Jacques Curie. Their experiment consisted of voltage being produced when prepared crystals, such as quartz, topaz, and Rochelle salt, had a force applied. SEE FIGURE 39–23. This current is used in crystal microphones, underwater hydrophones, and certain stethoscopes. The voltage created is called piezoelectricity. A gas grille igniter uses the principle of piezoelectricity to produce a spark, and engine knock sensor (KS) use piezoelectricity to create a voltage signal for use as an input as an engine computer input signal. CHEMICAL Two different materials (usually metals) placed in a conducting and reactive chemical solution create a difference in potential, or voltage, between them. This principle is called electrochemistry and is the basis of the automotive battery.
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MAGNETISM Electricity can be produced if a conductor is moved through a magnetic field or a moving magnetic field is moved near a conductor. This is the principle of how many automotive devices work, including:
Starter motor
Alternator
Ignition coils
Solenoids and relays
CONDUCTORS AND RESISTANCE All conductors have some resistance to current flow. The following are principles of conductors and their resistance.
If the conductor length is doubled, its resistance doubles. This is the reason why battery cables are designed to be as short as possible.
If the conductor diameter is increased, its resistance is reduced. This is the reason starter motor cables are larger in diameter than other wiring in the vehicle.
As the temperature increases, the resistance of the conductor also increases. This is the reason for installing heat shields on some starter motors. The heat shield helps to protect the conductors (copper wiring inside the starter) from excessive engine heat and so reduces the resistance of starter circuits. Because a conductor increases in resistance with increased temperature, the conductor is called a positive temperature coefficient (PTC) resistor.
FIRST AND SECOND BAND COLORS REPRESENT NUMBERS
EXAMPLES:
THIRD BAND COLOR MEANS NUMBER OF ZEROS
470 Ω GOLD (IF 5%)
YELLOW, VIOLET, BROWN (1 ZERO) (4) (7) 3900 Ω GOLD (IF 5%)
FOURTH BAND REPRESENTS TOLERANCE (ACCURACY) BLACK = 0 BROWN = 1 RED = 2 ORANGE = 3 YELLOW = 4 GREEN = 5 BLUE = 6 VIOLET = 7 GRAY = 8 WHITE = 9
ORANGE, WHITE, RED (2 ZEROS) (3) (9)
FOURTH BAND TOLERANCE CODE NO FOURTH BAND = ±20% SILVER = ±10% * GOLD = ±5% RED = ±2% BROWN = ±1% * GOLD IS THE MOST COMMONLY AVAILABLE RESISTOR TOLERANCE.
FIGURE 39–24 This figure shows a resistor color-code interpretation.
1
Silver
2
Copper
3
Gold
4
Aluminum
5
Tungsten
6
Zinc
7
Brass (copper and zinc)
8
Platinum
9
Iron
B+ REFERENCE VOLTAGE
10
Nickel
11
Tin
SIGNAL VOLTAGE (VARIABLE WITH POSITION OF MOVABLE CONTACT)
12
Steel
13
Lead
CHART 39–1
FIGURE 39–25 A typical carbon resistor.
GROUND (0 VOLT) MOVABLE CONTACT
FIGURE 39–26 A three-wire variable resistor is called a potentiometer.
Conductor ratings (starting with the best). B+
Materials used in the conductor have an impact on its resistance. Silver has the lowest resistance of any conductor, but is expensive. Copper is the next lowest in resistance and is reasonably priced. SEE CHART 39–1 for a comparison of materials.
RESISTORS
OUTPUT TERMINAL MOVABLE CONTACT
FIGURE 39–27 A two-wire variable resistor is called a rheostat.
VARIABLE RESISTORS Two basic types of mechanically operated variable resistors are used in automotive applications.
A potentiometer is a three-terminal variable resistor where a wiper contact provides a variable voltage output. SEE FIGURE 39–26. Potentiometers are most commonly used as throttle position (TP) sensors on computer-equipped engines. A potentiometer is also used to control audio volume, bass, treble, balance, and fade.
Another type of mechanically operated variable resistor is the rheostat. A rheostat is a two-terminal unit in which all of the current flows through the movable arm. SEE FIGURE 39–27. A rheostat is commonly used for a dash light dimmer control.
FIXED RESISTORS
Resistance is the opposition to current flow. Resistors represent an electrical load, or resistance, to current flow. Most electrical and electronic devices use resistors of specific values to limit and control the flow of current. Resistors can be made from carbon or from other materials that restrict the flow of electricity and are available in various sizes and resistance values. Most resistors have a series of painted color bands around them. These color bands are coded to indicate the degree of resistance. SEE FIGURES 39–24 AND 39–25.
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REVIEW QUESTIONS 1. What is electricity?
3. What are three examples of conductors and three examples of insulators?
2. What are the ampere, volt, and ohm?
4. What are the four sources of electricity?
CHAPTER QUIZ 1. An electrical conductor is an element with ______________ electrons in its outer orbit. a. Less than 2 c. Exactly 4 b. Less than 4 d. More than 4 2. Like charges ______________. a. Attract c. Neutralize each other b. Repel d. Add 3. Carbon and silicon are examples of ______________. a. Semiconductors c. Conductors b. Insulators d. Photoelectric materials 4. Which unit of electricity does the work in a circuit? a. Volt c. Ohm b. Ampere d. Coulomb 5. As temperature increases, ______________. a. The resistance of a conductor decreases b. The resistance of a conductor increases c. The resistance of a conductor remains the same d. The voltage of the conductor decreases 6. The ______________ is a unit of electrical pressure. a. Coulomb c. Ampere b. Volt d. Ohm
chapter
40
7. Technician A says that a two-wire variable resistor is called a rheostat. Technician B says that a three-wire variable resistor is called a potentiometer. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 8. Creating electricity by exerting a force on a crystal is called ______________. a. Electrochemistry c. Thermoelectricity b. Piezoelectricity d. Photoelectricity 9. The fact that a voltage can be created by exerting force on a crystal is used in which type of sensor? a. Throttle position (TP) b. Manifold absolute pressure (MAP) c. Barometric pressure (BARO) d. Knock sensor (KS) 10. A potentiometer, a three-wire variable resistance, is used in which type of sensor? a. Throttle position (TP) b. Manifold absolute pressure (MAP) c. Barometric pressure (BARO) d. Knock sensor (KS)
ELECTRICAL CIRCUITS AND OHM’S LAW
OBJECTIVES: After studying Chapter 40, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic Systems Diagnosis). • Explain Ohm’s law. • Identify the parts of a complete circuit. • Explain Watt’s law. • Describe the characteristics of an open, a short-to-ground, and a short-to-voltage. KEY TERMS: Circuit 428 • Complete circuit 428 • Continuity 428 • Electrical load 429 • Grounded 431 • High resistance 431 • Load 428 • Ohm’s law 431 • Open circuit 429 • Power path 429 • Power source 429 • Protection 429 • Return path (ground) 429 • Shorted 430 • Short-to-ground 430 • Short-to-voltage 430 • Watt 432 • Watt’s law 432
CIRCUITS DEFINITION A circuit is a complete path that electrons travel from a power source (such as a battery) through a load such as a light bulb and back to the power source. It is called a circuit because the current must start and finish at the same place (power source).
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For any electrical circuit to work at all, it must be continuous from the battery (power), through all the wires and components, and back to the battery (ground). A circuit that is continuous throughout is said to have continuity.
PARTS OF A COMPLETE CIRCUIT Every complete circuit contains the following parts. SEE FIGURE 40–1.
POWER SOURCE (BATTERY) FINISH
START
CONDUCTOR (WIRE) LIGHT BULB PROTECTION (FUSE) SWITCH
RETURN CONDUCTOR (WIRE)
LOAD (LIGHT BULB)
FIGURE 40–1 All complete circuits must have a power source, a power path, protection (fuse), an electrical load (light bulb in this case), and a return path back to the power source.
BATTERY
FIGURE 40–3 An electrical switch opens the circuit and no current flows. The switch could also be on the return (ground) path wire.
BROKEN WIRE
INTERNALLY OPEN PART
BATTERY
GROUND SYMBOL
(EXTREMELY HIGH RESISTANCE WILL APPEAR AS OPEN CIRCUIT)
GROUND CONNECTION BLOWN FUSE
BODY SHEET METAL: ENGINE BLOCK, ETC.
FIGURE 40–2 The return path back to the battery can be any electrical conductor, such as a copper wire or the metal frame or body of the vehicle.
1. A power source, such as a vehicle’s battery 2. Protection from harmful overloads (excessive current flow) (Fuses, circuit breakers, and fusible links are examples of electrical circuit protection devices.) 3. The power path for the current to flow through from the power source to the resistance (This path from a power source to the load—a light bulb in this example—is usually an insulated copper wire.) 4. The electrical load or resistance which converts electrical energy into heat, light, or motion 5. A return path (ground) for the electrical current from the load back to the power source so that there is a complete circuit (This return, or ground, path is usually the metal body, frame, ground wires, and engine block of the vehicle. SEE FIGURE 40–2). 6. Switches and controls that turn the circuit on and off ( SEE FIGURE 40–3).
CORRODED CONNECTION
LOOSE CONNECTION
FIGURE 40–4 Examples of common causes of open circuits. Some of these causes are often difficult to find.
TECH TIP “Open” Is a Four-Letter Word An open in a circuit breaks the path of current flow. The open can be any break in the power side, load, or ground side of a circuit. A switch is often used to close and open a circuit to turn it on and off. Just remember, Open ⫽ no current flow Closed ⫽ current flow Trying to locate an open circuit in a vehicle is often difficult and may cause the technician to use other fourletter words, such as “HELP”!
Open circuits have the following features:
CIRCUIT FAULT TYPES OPEN CIRCUITS An open circuit is any circuit that is not complete, or that lacks continuity, such as a broken wire. SEE FIGURE 40–4.
1. No current at all will flow through an open circuit. 2. An open circuit may be created by a break in the circuit or by a switch that opens (turns off) the circuit and prevents the flow of current. 3. In any circuit containing a power load and ground, an opening anywhere in the circuit will cause the circuit not to work.
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SHORT-TO-VOLTAGE
SHORT-TO-GROUND
SWITCH
SWITCH
SWITCH
BATTERY
BATTERY
BODY OF VEHICLE
FIGURE 40–5 A short circuit permits electrical current to bypass some or all of the resistance in the circuit. PROTECTION DEVICE (FUSE)
CONTROL DEVICE (SWITCH OPEN)
BODY OF VEHICLE
FIGURE 40–7 A short-to-ground affects the power side of the circuit. Current flows directly to the ground return, bypassing some or all of the electrical loads in the circuit. There is no current in the circuit past the short. A short-to ground will also cause the fuse to blow. REAL WORLD FIX
–
+
POWER SOURCE (BATTERY)
RETURN CONDUCTOR (GROUND)
(SWITCH CLOSED)
CONDUCTOR (WIRE) LOAD (BULB)
RETURN CONDUCTOR GROUND
FIGURE 40–6 A fuse or circuit breaker opens the circuit to prevent possible overheating damage in the event of a short circuit. 4. A light switch in a home and the headlight switch in a vehicle are examples of devices that open a circuit to control its operation. 5. A fuse will blow (open) when the current in the circuit exceeds the fuse rating. This stops the current flow to prevent any harm to the components or wiring as a result of the fault.
SHORT-TO-VOLTAGE
If a wire (conductor) or component is shorted to voltage, it is commonly referred to as being shorted. A short-to-voltage occurs when the power side of one circuit is electrically connected to the power side of another circuit. SEE FIGURE 40–5. A short circuit has the following features: 1. It is a complete circuit in which the current usually bypasses some or all of the resistance in the circuit. 2. It involves the power side of the circuit. 3. It involves a copper-to-copper connection (two power-side wires touching together). 4. It is also called a short-to-voltage. 5. It usually affects more than one circuit. In this case if one circuit is electrically connected to another circuit, one of the circuits may operate when it is not supposed to because it is being supplied power from another circuit. 6. It may or may not blow a fuse. SEE FIGURE 40–6.
SHORT-TO-GROUND A short-to-ground is a type of short circuit that occurs when the current bypasses part of the normal circuit
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The Short-to-Voltage Story A technician was working on a Chevrolet pickup truck with the following unusual electrical problems. 1. When the brake pedal was depressed, the dash light and the side marker lights would light. 2. The turn signals caused all lights to blink and the fuel gauge needle to bounce up and down. 3. When the brake lights were on, the front parking lights also came on. The technician tested all fuses using a conventional test light and found them to be okay. All body-to-engine block ground wires were clean and tight. All bulbs were of the correct trade number as specified in the owner’s manual. NOTE: Using a single-filament bulb (such as a #1156) in the place of a dual-filament bulb (such as a #1157) could also cause many of these same problems. Because most of the trouble occurred when the brake pedal was depressed, the technician decided to trace all the wires in the brake light circuit. The technician discovered the problem near the exhaust system. A small hole in the tailpipe (after the muffler) directed hot exhaust gases to the wiring harness containing all of the wires for circuits at the rear of the truck. The heat had melted the insulation and caused most of the wires to touch. Whenever one circuit was activated (such as when the brake pedal was applied), the current had a complete path to several other circuits. A fuse did not blow because there was enough resistance in the circuits being energized, so the current (in amperes) was too low to blow any fuses. and flows directly to ground. A short-to-ground has the following features. 1. Because the ground return circuit is metal (vehicle frame, engine, or body), it is often identified as having current flowing from copper to steel. 2. It occurs any place where a power path wire accidentally touches a return path wire or conductor. SEE FIGURE 40–7.
WATER HAS 12 FEET OF POTENTIAL ENERGY
WATER FLOW IS CONSTANT, WATER (AMPERES) DOES THE WORK WHILE THE PRESSURE (VOLTAGE) IS DROPPED TO ZERO
E I
R
I AMPERES (CURRENT) R OHMS (RESISTANCE) E VOLTS (ELECTROMOTIVE FORCE)
E
E I
I
12 FEET WATER HAS NO (0 FEET) POTENTIAL ENERGY 0 FEET
POND
FIGURE 40–8 Electrical flow through a circuit is similar to water flowing over a waterwheel. The more water (amperes in electricity), the greater the amount of work (waterwheel). The amount of water remains constant, yet the pressure (voltage in electricity) drops as the current flows through the circuit.
TECH TIP Think of a Waterwheel A beginner technician cleaned the positive terminal of the battery when the starter was cranking the engine slowly. When questioned by the shop foreman as to why only the positive post had been cleaned, the technician responded that the negative terminal was “only a ground.” The foreman reminded the technician that the current, in amperes, is constant throughout a series circuit (such as the cranking motor circuit). If 200 amperes leave the positive post of the battery, then 200 amperes must return to the battery through the negative post. The technician could not understand how electricity can do work (crank an engine), yet return the same amount of current, in amperes, as left the battery. The shop foreman explained that even though the current is constant throughout the circuit, the voltage (electrical pressure or potential) drops to zero in the circuit. To explain further, the shop foreman drew a waterwheel. SEE FIGURE 40–8. As water drops from a higher level to a lower level, high potential energy (or voltage) is used to turn the waterwheel and results in low potential energy (or lower voltage). The same amount of water (or amperes) reaches the pond under the waterwheel as started the fall above the waterwheel. As current (amperes) flows through a conductor, it performs work in the circuit (turns the waterwheel) while its voltage (potential) drops.
3. A defective component or circuit that is shorted to ground is commonly called grounded.
RE I
EIR
IE R
FIGURE 40–9 To calculate one unit of electricity when the other two are known, simply use your finger and cover the unit you do not know. For example, if both voltage (E) and resistance (R) are known, cover the letter I (amperes). Notice that the letter E is above the letter R, so divide the resistor’s value into the voltage to determine the current in the circuit.
If there is high resistance anywhere in a circuit, it may cause the following problems. 1. Slow operation of a motor-driven unit, such as the windshield wipers or blower motor 2. Dim lights 3. “Clicking” of relays or solenoids 4. No operation of a circuit or electrical component
OHM’S LAW DEFINITION
The German physicist, George Simon Ohm, established that electric pressure (EMF) in volts, electrical resistance in ohms, and the amount of current in amperes flowing through any circuit are all related. Ohm’s law states: It requires 1 volt to push 1 ampere through 1 ohm of resistance. This means that if the voltage is doubled, then the number of amperes of current flowing through a circuit will also double if the resistance of the circuit remains the same.
FORMULAS Ohm’s law can also be stated as a simple formula used to calculate one value of an electrical circuit if the other two are known. SEE FIGURE 40–9. If, for example, the current (I) is unknown but the voltage (E) and resistance (R) are known, then Ohm’s Law can be used to find the answer.
4. A short-to-ground almost always results in a blown fuse, damaged connectors, or melted wires.
HIGH RESISTANCE
R
I5
E R
High resistance can be caused by any of
the following:
where
Corroded connections or sockets
I ⫽ Current in amperes (A)
Loose terminals in a connector
E ⫽ Electromotive force (EMF) in volts (V)
Loose ground connections
R ⫽ Resistance in ohms (Ω) E L E C T RI C AL C I RC U I T S AN D OH M ’S L A W
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VOLTAGE
RESISTANCE
AMPERAGE
Up
Down
Up
Up
Same
Up
Up
Up
Same
Same
Down
Up
Same
Same
Same
Same
Up
Down
Down
Up
Down
Down
Same
Down
CHART 40–1 Ohm’s law relationship with the three units of electricity.
CLOSED CIRCUIT LIGHT BULB RETURN PATH FUSE
POWER SIDE
TECH TIP Wattage Increases by the Square of the Voltage The brightness of a light bulb, such as an automotive headlight or courtesy light, depends on the number of watts available. The watt is the unit by which electrical power is measured. If the battery voltage drops, even slightly, the light becomes noticeably dimmer. The formula for calculating power (P) in watts is P ⫽ I ⫻ E. This can also be expressed as Watts ⫽ Amps ⫻ Volts. E E According to Ohm’s law, I 5 . Therefore, can R R be substituted for I in the previous formula resulting in E2 E P 5 3 E or P 5 . R R E2 means E multiplied by itself. A small change in the voltage (E) has a big effect on the total brightness of the bulb. (Remember, household light bulbs are sold according to their wattage.) Therefore, if the voltage to an automotive bulb is reduced, such as by a poor electrical connection, the brightness of the bulb is greatly affected. A poor electrical ground causes a voltage drop. The voltage at the bulb is reduced and the bulb’s brightness is reduced.
START
FINISH
The values for the voltage (12) and the resistance (4) were substituted for the variables E and R, and I is thus 3 amperes
BATTERY
a FIGURE 40–10 This closed circuit includes a power source, power-side wire, circuit protection (fuse), resistance (bulb), and return path wire. In this circuit, if the battery has 12 volts and the electrical load has 4 ohms, then the current through the circuit is 4 amperes. 1. Ohm’s law can determine the resistance if the volts and E amperes are known: R 5 I 2. Ohm’s law can determine the voltage if the resistance (ohms) and amperes are known: E ⫽ I ⫻ R 3. Ohm’s law can determine the amperes if the resistance and E voltage are known: I 5 R NOTE: Before applying Ohm’s law, be sure that each unit of electricity is converted into base units. For example, 10 KΩ should be converted to 10,000 ohms and 10 mA should be converted into 0.010 A.
SEE CHART 40–1.
OHM’S LAW APPLIED TO SIMPLE CIRCUITS
If a battery with 12 volts is connected to a resistor of 4 ohms, as shown in FIGURE 40–10, how many amperes will flow through the circuit? Using Ohm’s law, we can calculate the number of amperes that will flow through the wires and the resistor. Remember, if two factors are known (volts and ohms in this example), the remaining factor (amperes) can be calculated using Ohm’s law. I5
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E 12 V 5 A R 4V
12 5 3b 4
If we want to connect a resistor to a 12 volt battery, we now know that this simple circuit requires 3 amperes to operate. This may help us for two reasons. 1. We can now determine the wire diameter that we will need based on the number of amperes flowing through the circuit. 2. The correct fuse rating can be selected to protect the circuit.
WATT’S LAW BACKGROUND James Watt (1736–1819), a Scottish inventor, first determined the power of a typical horse while measuring the amount of coal being lifted out of a mine. The power of one horse was determined to be 33,000 foot-pounds per minute. Electricity can also be expressed in a unit of power called a watt and the relationship is known as Watt’s law, which states: A watt is a unit of electrical power represented by a current of 1 ampere through a circuit with a potential difference of 1 volt. FORMULAS A watt is a unit of electrical power represented by a current of 1 ampere through a circuit with a potential difference of 1 volt. The symbol for a watt is the capital letter W. The formula for watts is: WIE Another way to express this formula is to use the letter P to represent the unit of power. The formula then becomes: PIE
P
P=
(watts)
E2 R
I= E R I=
P = I2 R
I
E
(amperes)
(volts) E=
FIGURE 40–11 To calculate one unit when the other two are known, simply cover the unknown unit to see what unit needs to be divided or multiplied to arrive at the solution.
P I
P=IE
POWER (WATTS)
E=
E R P I
R= E=IR
HINT: An easy way to remember this equation is that it spells “pie.” Engine power is commonly rated in watts or kilowatts (1,000 watts equal 1 kilowatt), because 1 horsepower is equal to 746 watts. For example, a 200 horsepower engine can be rated as having the power equal to 149,200 watts or 149.2 kilowatts (kW). To calculate watts, both the current in amperes and the voltage in the circuit must be known. If any two of these factors are known, then the other remaining factor can be determined by the following equations: P I E (watts equal amperes times voltage) I
P (amperes equal watts divided by voltage) E
E
P (voltage equals watts divided by amperes) I
I=
CURRENT (AMPERES)
PRESSURE RESISTANCE (OHMS) (VOLTS
PR
R=
P E
P R
R= E I
E2 P
P I2
FIGURE 40–12 “Magic circle” of most formulas for problems involving Ohm’s law. Each quarter of the “pie” has formulas used to solve for a particular unknown value: current (amperes), in the upper right segment; resistance (ohms), in the lower right; voltage (E), in the lower left; and power (watts), in the upper left. A Watt’s circle can be drawn and used like the Ohm’s law circle diagram. SEE FIGURE 40–11.
MAGIC CIRCLE
The formulas for calculating any combination of electrical units are shown in FIGURE 40–12. It is almost impossible to remember all of these formulas, so this one circle showing all of the formulas is nice to have available if needed.
REVIEW QUESTIONS 1. What is included in a complete electrical circuit?
4. What is Ohm’s law?
2. What is the difference between a short-to-voltage and a shortto-ground?
5. What occurs to current flow (amperes) and wattage if the resistance of a circuit is increased because of a corroded connection?
3. What is the difference between an electrical open and a short?
CHAPTER QUIZ 1. If an insulated wire rubbed through a part of the insulation and the wire conductor touched the steel body of a vehicle, the type of failure would be called a(n) ______________. a. Short-to-voltage c. Open b. Short-to-ground d. Chassis ground 2. If two insulated wires were to melt together where the copper conductors touched each other, the type of failure would be called a(n) ______________. a. Short-to-voltage c. Open b. Short-to-ground d. Floating ground 3. If 12 volts are being applied to a resistance of 3 ohms, ______________ amperes will flow. a. 12 c. 4 b. 3 d. 36
4. How many watts are consumed by a light bulb if 1.2 amperes are measured when 12 volts are applied? a. 14.4 watts c. 10 watts b. 144 watts d. 0.10 watt 5. How many watts are consumed by a starter motor if it draws 150 amperes at 10 volts? a. 15 watts c. 1,500 watts b. 150 watts d. 15,000 watts 6. High resistance in an electrical circuit can cause ______________. a. Dim lights b. Slow motor operation c. Clicking of relays or solenoids d. All of the above
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7. If the voltage increases in a circuit, what happens to the current (amperes) if the resistance remains the same? a. Increases c. Remains the same b. Decreases d. Cannot be determined 8. If 200 amperes flow from the positive terminal of a battery and operate the starter motor, how many amperes will flow back to the negative terminal of the battery? a. Cannot be determined b. Zero c. One half (about 100 amperes) d. 200 amperes
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9. What is the symbol for voltage used in calculations? a. R b. E c. EMF d. I 10. Which circuit failure is most likely to cause the fuse to blow? a. Open b. Short-to-ground c. Short-to-voltage d. High resistance
SERIES, PARALLEL, AND SERIES-PARALLEL CIRCUITS
OBJECTIVES: After studying Chapter 41, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic System Diagnosis). • Identify a series circuit. • Identify a parallel circuit. • Identify a series-parallel circuit. • Calculate the total resistance in a parallel circuit. • State Kirchhoff’s voltage law. • Calculate voltage drops in a series circuit. • Explain series and parallel circuit laws. • State Kirchhoff’s current law. • Identify where faults in a series-parallel circuit can be detected or determined. KEY TERMS: Branches 438 • Combination circuit 441 • Compound circuit 441 • Kirchhoff’s current law 438 • Kirchhoff’s voltage law 435 • Leg 438 • Parallel circuit 438 • Series circuit 434 • Series-parallel circuits 441 • Shunt 438 • Total circuit resistance 439 • Voltage drop 436
BULB 2 (2 )
SERIES CIRCUITS A series circuit is a complete circuit that has more than one electrical load where all of the current has only one path to flow through all of the loads. Electrical components such as fuses and switches are generally not considered to be included in the determination of a series circuit. The circuit must be continuous or have continuity in order for current to flow through the circuit. NOTE: Because an electrical load needs both a power and a ground to operate, a break (open) anywhere in a series circuit will cause the current in the circuit to stop.
BULB 1 (1 ) BULB 3 (3 )
12-V BATTERY
OHM’S LAW AND SERIES CIRCUITS As explained earlier, a series circuit is a circuit containing more than one resistance in which all current must flow through all resistances in the circuit. Ohm’s law can be used to calculate the value of one unknown (voltage, resistance, or amperes) if the other two values are known. Because all current flows through all resistances, the total resistance is the sum (addition) of all resistances. SEE FIGURE 41–1.
434
CHAPTER 4 1
FIGURE 41–1 A series circuit with three bulbs. All current flows through all resistances (bulbs). The total resistance of the circuit is the sum of the total resistance of the bulbs, and the bulbs will light dimly because of the increased resistance and the reduction of current flow (amperes) through the circuit. The total resistance of the circuit shown here is 6 ohms (1 Ω ⫹ 2 Ω ⫹ 3 Ω). The formula for total resistance (RT) for a series circuit is: RT R1 R2 R3 . . .
2
BULB 2
(VOLTMETER)
(VOLTMETER)
0V
12 V
(FUSE)
(BULB)
(R2) 1 (R1) BULB 1 0V
(SWITCH)
(GROUND)
12-V BATTERY 12 V
FIGURE 41–2 A series circuit with two bulbs.
TECH TIP Farsighted Quality of Electricity
(GROUND)
FIGURE 41–3 As current flows through a circuit, the voltage drops in proportion to the amount of resistance in the circuit. Most, if not all, of the resistance should occur across the load such as the bulb in this circuit. All of the other components and wiring should produce little, if any, voltage drop. If a wire or connection did cause a voltage drop, less voltage would be available to light the bulb and the bulb would be dimmer than normal.
Electricity almost seems to act as if it “knows” what resistances are ahead on the long trip through a circuit. If the trip through the circuit has many high-resistance components, very few electrons (amperes) will choose to attempt to make the trip. If a circuit has little or no resistance (for example, a short circuit), then as many electrons (amperes) as possible attempt to flow through the complete circuit. If the flow exceeds the capacity of the fuse or the circuit breaker, then the circuit is opened and all current flow stops.
6 BULB 3
4
BULB 2
2
Using Ohm’s law to find the current flow, we have I E/R 12 V/6 Ω 2 A
12-V BATTERY BULB 1
Therefore, with a total resistance of 6 ohms using a 12-volt battery in the series circuit shown, 2 amperes of current will flow through the entire circuit. If the amount of resistance in a circuit is reduced, more current will flow. In FIGURE 41–2, one resistance has been eliminated and now the total resistance is 3 ohms (1 Ω ⫹ 2 Ω). Using Ohm’s law to calculate current flow yields 4 amperes. I E/R 12 V/3 Ω 4 A Notice that the current flow was doubled (4 amperes instead of 2 amperes) when the resistance was cut in half (from 6 ohms to 3 ohms).
KIRCHHOFF’S VOLTAGE LAW The voltage that is applied through a series circuit drops with each resistor in a manner similar to that in which the strength of an athlete drops each time a strenuous physical feat is performed. The greater the resistance, the greater the drop in voltage. A German physicist, Gustav Robert Kirchhoff (1824–1887), developed laws about electrical circuits. His second law, Kirchhoff’s
SERIES CIRCUIT
FIGURE 41–4 In a series circuit the voltage is dropped or lowered by each resistance in the circuit. The higher the resistance, the greater the drop in voltage.
voltage law, concerns voltage drops. It states: The voltage around any closed circuit is equal to the sum (total) of the voltage drops across the resistances.
APPLYING KIRCHHOFF’S VOLTAGE LAW Kirchhoff states in his second law that the voltage will drop in proportion to the resistance and that the total of all voltage drops will equal the applied voltage. SEE FIGURE 41–3. Using FIGURE 41–4, the total resistance of the circuit can be determined by adding the individual resistances (2 Ω ⫹ 4 Ω ⫹ 6 Ω ⫽ 12 Ω). The current through the circuit is determined by using Ohm’s law, I ⫽ E/R ⫽ 12 V/12 Ω ⫽ 1 A. Therefore, in the circuit shown, the following values are known: Resistance ⫽ 12 Ω Voltage ⫽ 12 V Current ⫽ 1 A SE RI E S, PARAL L E L , AN D SE RI E S-PARALL EL C IRC U IT S
435
2
4 OHMS 8 VOLTS
4V
V 12-V BATTERY 4 A. I = E/R (TOTAL “R ” = 6 ) = 12 V/6 = 2A B. E = I/R (VOLTAGE DROP ) AT 2 RESISTANCE = E = 2 x 2 = 4V AT 4 RESISTANCE = E = 2 x 4 = 8V C. 4 + 8 = 12 V SUM OF VOLTAGE DROP EQUALS APPLIED VOLTAGE
FIGURE 41–5 A voltmeter reads the differences of voltage between the test leads. The voltage read across a resistance is the voltage drop that occurs when current flows through a resistance. A voltage drop is also called an “IR” drop because it is calculated by multiplying the current (I) through the resistance (electrical load) by the value of the resistance (R). Everything is known except the voltage drop caused by each resistance. The voltage drop can be determined by using Ohm’s law and calculating for voltage (E) using the value of each resistance individually: EIR where E ⫽ Voltage I ⫽ Current in the circuit (remember, the current is constant in a series circuit; only the voltage varies) R ⫽ Resistance of only one of the resistances
4 VOLTS 2 OHMS
12 VOLTS
V
8V
2 AMPS
FIGURE 41–6 In this series circuit with a 2-ohm resistor and a 4-ohm resistor, current (2 amperes) is the same throughout even though the voltage drops across each resistor.
?
FREQUENTLY ASKED QUESTION
Why Check the Voltage Drop Instead of Measuring the Resistance? Imagine a wire with all strands cut except for one. An ohmmeter can be used to check the resistance of this wire and the resistance would be low, indicating that the wire was okay. But this one small strand cannot properly carry the current (amperes) in the circuit. A voltage drop test is therefore a better test to determine the resistance in components for two reasons: • An ohmmeter can only test a wire or component that has been disconnected from the circuit and is not carrying current. The resistance can, and does, change when current flows. • A voltage drop test is a dynamic test because as the current flows through a component, the conductor increases in temperature, which in turn increases resistance. This means that a voltage drop test is testing the circuit during normal operation and is therefore the most accurate way of determining circuit conditions. A voltage drop test is also easier to perform because the resistance does not have to be known, only that the unwanted loss of voltage in a circuit should be less than 3% or less than about 0.14 volts for any 12-volt circuit.
The voltage drops are as follows: Voltage drop for bulb 1: E I R 1 A 2 Ω 2 V Voltage drop for bulb 2: E I R 1 A 4 Ω 4 V Voltage drop for bulb 3: E I R 1 A 6 Ω 6 V NOTE: Notice that the voltage drop is proportional to the resistance. In other words, the higher the resistance, the greater the voltage drop. A 6-ohm resistance dropped the voltage three times as much as the voltage drop created by the 2-ohm resistance.
resistor. This type of resistor can be changed and therefore varies the voltage to the dash light bulbs. A high voltage to the bulbs causes them to be bright, and a low voltage results in a dim light. 2. Blower motor (heater or air-conditioning fan). Speeds are usually controlled by a fan switch sending current through high-, medium-, or low-resistance wire resistors. The highest resistance will drop the voltage the most, causing the motor to run at the lowest speed. The highest speed of the motor will occur when no resistance is in the circuit and full battery voltage is switched to the blower motor.
According to Kirchhoff, the sum (addition) of the voltage drops should equal the applied voltage (battery voltage): Total of voltage drops 2 V 4 V 6 V 12 V Battery voltage
SERIES CIRCUIT LAWS
This illustrates Kirchhoff’s second (voltage) law. Another example is illustrated in FIGURE 41–5.
LAW 1
The total resistance in a series circuit is the sum total of the individual resistances. The resistance values of each electrical load are simply added together.
USE OF VOLTAGE DROPS Voltage drops, due to built-in resistance, are used in automotive electrical systems to drop the voltage in the following examples.
LAW 2
The current is constant throughout the entire circuit. SEE FIGURE 41–6. If 2 amperes of current leave the battery, 2 amperes of current return to the battery.
1. Dash lights. Most vehicles are equipped with a method of dimming the brightness of the dash lights by turning a variable
LAW 3
Although the current (in amperes) is constant, the voltage drops across each resistance in the circuit. The voltage
436
CHAPTER 4 1
3A
3
1
4A
R1
4A
R1
+
+
12 VOLT
3A
R2
VOLTS = ?
–
1
– R2
3A
R3
?
FIGURE 41–7 Example 1. 2A
1
4A
FIGURE 41–9 Example 3. 3
2A
2
?A
R1
?A
R1
+
+ R2
12 VOLT
1
R2
12 VOLTS
–
2
– R3
R3
2A
4A
?
2A
FIGURE 41–8 Example 2. drop across each load is proportional to the value of the resistance compared to the total resistance. For example, if the resistance is one-half of the total resistance, the voltage drop across that resistance will be one-half of the applied voltage. The sum total of all individual voltage drops equals the applied source voltage.
2
?A
?A
FIGURE 41–10 Example 4. The total resistance of R1 (3 ohms) and R2 (1 ohm) equals 4 ohms so that the value of R3 is the difference between the total resistance (6 ohms) and the value of the known resistance (4 ohms). 6 4 2 ohms R3
Example 3:
SERIES CIRCUIT EXAMPLES Each of the four examples includes solving for the following:
Total resistance in the circuit
Current flow (amperes) through the circuit
Voltage drop across each resistance
SEE FIGURE 41–9. The unknown value in this problem is the voltage of the battery. To solve for voltage, use Ohm’s law (E ⫽ I ⫻ R). The “R” in this problem refers to the total resistance (RT). The total resistance of a series circuit is determined by adding the values of the individual resistors. RT 1 Ω 1 Ω 1 Ω RT 3 Ω Placing the value for the total resistance (3 Ω) into the equation results in a battery voltage of 12 volts.
Example 1:
SEE FIGURE 41–7.
E4A3Ω E 12 volts
The unknown in this problem is the value of R2. The total resistance, however, can be calculated using Ohm’s law. RTotal E/I 12 volts/3 A 4 Ω Because R1 is 3 ohms and the total resistance is 4 ohms, the value of R2 is 1 ohm.
Example 2:
Example 4: SEE FIGURE 41–10. The unknown in this example is the current (amperes) in the circuit. To solve for current, use Ohm’s law. I E/R 12 volts/6 ohms 2 A
SEE FIGURE 41–8. The unknown in this problem is the value of R3. The total resistance, however, can be calculated using Ohm’s law. RTotal E/I 12 volts/2 A 6 Ω
Notice that the total resistance in the circuit (6 ohms) was used in this example, which is the total of the three individual resistors (2 Ω ⫹ 2 Ω ⫹ 2 Ω ⫽ 6 Ω). The current through the circuit is two amperes.
SE RI E S, PARAL L E L , AN D SE RI E S-PARAL L EL C IRC U IT S
437
6 AMPS
6
2 AMPS
12 VOLTS 3
4 AMPS 6 OHMS
3 OHMS
6 AMPS 2A
4A
FIGURE 41–12 The current in a parallel circuit splits (divides) according to the resistance in each branch.
JUNCTION A
TECH TIP 6A
The Path of Least Resistance
12-V BATTERY
FIGURE 41–11 The amount of current flowing into junction point A equals the total amount of current flowing out of the junction.
PARALLEL CIRCUITS A parallel circuit is a complete circuit that has more than one path for the current. The separate paths which split and meet at junction points are called branches, legs, or shunts. The current flow through each branch or leg varies depending on the resistance in that branch. A break or open in one leg or section of a parallel circuit does not stop the current flow through the remaining legs of the parallel circuit.
There is an old saying that electricity will always take the path of least resistance. This is true, especially if there is a fault such as in the secondary (high-voltage) section of the ignition system. If there is a path to ground that is lower than the path to the spark plug, the high-voltage spark will take the path of least resistance. In a parallel circuit where there is more than one path for the current to flow, most of the current will flow through the branch with the lower resistance. This does not mean that all of the current will flow through the lowest resistance, because the other path does provide a path to ground, and the amount of current flow through the other branches is determined by the resistance and the applied voltage according to Ohm’s law. Therefore, the only place where electricity takes the path of least resistance is in a series circuit where there are not other paths for the current to flow.
LAW 3
KIRCHHOFF’S CURRENT LAW Kirchhoff’s current law (his first law) states: The current flowing into any junction of an electrical circuit is equal to the current flowing out of that junction. This first law can be illustrated using Ohm’s law, as seen in FIGURE 41–11. Kirchhoff’s law states that the amount of current flowing into junction A will equal the current flowing out of junction A. Because the 6-ohm leg requires 2 amperes and the 3-ohm resistance leg requires 4 amperes, it is necessary that the wire from the battery to junction A be capable of handling 6 amperes. Also notice that the sum of the current flowing out of a junction (2 ⫹ 4 ⫽ 6 A) is equal to the current flowing into the junction (6 A), proving Kirchhoff’s current law.
PARALLEL CIRCUIT LAWS LAW 1
The total resistance of a parallel circuit is always less than that of the smallest-resistance leg. This occurs because not all of the current flows through each leg or branch. With many branches, more current can flow from the battery just as more vehicles can travel on a road with five lanes compared to a road with only one or two lanes.
LAW 2
The voltage is the same for each leg of a parallel circuit.
438
CHAPTER 4 1
The sum of the individual currents in each leg will equal the total current. The amount of current flow through a parallel circuit may vary for each leg depending on the resistance of that leg. The current flowing through each leg results in the same voltage drop (from the power side to the ground side) as for every other leg of the circuit. SEE FIGURE 41–12.
NOTE: A parallel circuit drops the voltage from source voltage to zero (ground) across the resistance in each leg of the circuit.
DETERMINING TOTAL RESISTANCE IN A PARALLEL CIRCUIT There are five methods commonly used to determine total resistance in a parallel circuit. NOTE: Determining the total resistance of a parallel circuit is very important in automotive service. Electronic fuelinjector and diesel engine glow plug circuits are two of the most commonly tested circuits where parallel circuit knowledge is required. Also, when installing extra lighting, the technician must determine the proper gauge wire and protection device.
ⴙ
ⴙ
SYMBOL FOR A BATTERY 12 Volts
ⴙ ⴙ
ⴙ 3⍀
6⍀
4⍀
ⴚ
ⴚ ⴚ
ⴚ
ⴚ
SYMBOL FOR AN ELECTRICAL RESISTANCE
FIGURE 42–14 A schematic showing two resistors in parallel connected to a 12-volt battery.
FIGURE 41–13 In a typical parallel circuit, each resistance has power and ground and each leg operates independently of the other legs of the circuit.
METHOD 1
The total current (in amperes) can be calculated first by treating each leg of the parallel circuit as a simple circuit. SEE FIGURE 41–13. Each leg has its own power and ground (⫺), and therefore, the current through each leg is independent of the current through any other leg. Current through the 3-Ω resistance I E/R 12 V/3 Ω 4 A Current through the 4-Ω resistance I E/R 12 V/4 Ω 3 A
ⴙ 12 V
R3 6⍀
A formula that can be used to find the total resistance for any number of resistances in parallel is 1/RT ⫽ 1/R1 ⫹ 1/R2 ⫹ 1/R3 ⫹ . . . To solve for RT for the three resistance legs in FIGURE 41–15, substitute the values of the resistances for R1, R2, and R3: 1/RT ⫽ 1/3 ⫹ 1/4 ⫹ 1/6. The fractions cannot be added together unless they all have the same denominator. The lowest common denominator in this example is 12. Therefore, 1/3 becomes 4/12, 1/4 becomes 3/12, and 1/6 becomes 2/12. 1/RT ⫽ 4/12 ⫹ 3/12 ⫹ 2/12 or 9/12. Cross multiplying RT ⫽ 12/9 ⫽ 1.33 Ω. Note that the result (1.33 Ω) is the same regardless of the method used (see Method 1). The most difficult part of using this method (besides using fractions) is determining the lowest common denominator, especially for circuits containing a wide range of ohmic values for the various legs. For an easier method using a calculator, see Method 4.
METHOD 4
This method uses an electronic calculator, commonly available at very low cost. Instead of determining the lowest common denominator as in Method 3, one can use the electronic calculator to convert the fractions to decimal equivalents. The memory buttons on most calculators can be used to keep a running total of the fractional values. Use FIGURE 41–16 and calculate the total resistance (RT) by pushing the indicated buttons on the calculator. Also SEE FIGURE 41–17.
If only two resistors are connected in parallel, the total resistance (RT) can be found using the formula RT ⫽ (R1 ⫻ R2) / (R1 ⫹ R2). For example, using the circuit in FIGURE 41–14 and substituting 3 ohms for R1 and 4 amperes for R2, RT ⫽ (3 ⫻ 4) / (3 ⫹ 4) ⫽ 12/7 ⫽ 1.7 Ω. Note that the total resistance (1.7 Ω) is smaller than that of the smallest-resistance leg of the circuit.
This formula can be used for more than two resistances in parallel, but only two resistances can be calculated at a time. After solving for RT for two resistors, use the value of RT as R1 and the additional resistance in parallel as R2.
R2 4⍀
METHOD 3
RT E/I 12 V/9 A 1.33 Ω
NOTE: Which resistor is R1 and which is R2 is not important. The position in the formula makes no difference in the multiplication and addition of the resistor values.
R1 3⍀
Then solve for another RT. Continue the process for all resistance legs of the parallel circuit. However, note that it might be easier to solve for RT when there are more than two resistances in parallel by using Method 3 or 4.
The total current flowing from the battery is the sum total of the individual currents for each leg. Total current from the battery is, therefore, 9 amperes (4 A ⫹ 3 A ⫹ 2 A ⫽ 9 A). If total circuit resistance (RT) is needed, Ohm’s law can be used to calculate it because voltage (E) and current (I) are now known.
METHOD 2
ⴚ
FIGURE 41–15 A parallel circuit with three resistors connected to a 12-volt battery.
Current through the 6-Ω resistance I E/R 12 V/6 Ω 2 A
Note that the total resistance (1.33 Ω) is smaller than that of the smallest-resistance leg of the parallel circuit. This characteristic of a parallel circuit holds true because not all current flows through all resistances as in a series circuit. Because the current has alternative paths to ground through the various legs of a parallel circuit, as additional resistances (legs) are added to a parallel circuit, the total current from the battery (power source) increases. Additional current can flow when resistances are added in parallel, because each leg of a parallel circuit has its own power and ground and the current flowing through each leg is strictly dependent on the resistance of that leg.
R2 4⍀
R1 3⍀
12 V
NOTE: This method can be used to find the total resistance of any number of resistances in parallel. The memory recall (MRC) and equals (⫽) buttons invert the answer to give the correct value for total resistance (1.33 Ω). The inverse (1/X or X⫺1) button can be used with the sum (SUM) button on scientific calculators without using the memory button. METHOD 5
This method can be easily used whenever two or more resistances connected in parallel are of the same value. SEE FIGURE 41–18. To calculate the total resistance (RT) of equal-value resistors, divide the number of equal resistors into the value of the resistance. RT ⫽ Value of equal resistance/Number of equal resistances ⫽ 12 Ω/4 ⫽ 3 Ω.
SE RI E S, PARAL L E L , AN D SE RI E S-PARALL EL C IRC U IT S
439
2A ⴙ 3⍀
12 V ⴚ
6⍀
4⍀
+ R1
VOLTAGE = ? 1
ⴜ
3 Mⴙ
1
ⴜ
4
Mⴙ
1
ⴜ
6
Mⴙ
ⴜ
TO SOLVE THIS PARALLEL CIRCUIT PROBLEM FOR R1 (TOTAL RESISTANCE), PUSH THE EXACT BUTTONS ON AN ELECTRONIC CALCULATOR NOTE: BE CERTAIN TO PUSH THE BUTTON. FAILURE TO DO SO WILL RESULT IN INCORRECT ANSWERS WHEN USING MOST CALCULATORS.
MRC
12 ⍀ R2
12 ⍀
–
=
2A
FIGURE 41–19 Example 1.
=
12 A
(ANSWER = 1.3333)
FIGURE 41–16 Using an electronic calculator to determine the total resistance of a parallel circuit.
+ R1
12 VOLTS ⴙ 20 ⍀
12 V
1000 ⍀
4 ⍀ R2
2 ⍀ R3
?⍀
–
45 ⍀
ⴚ
USE AN ELECTRONIC CALCULATOR TO SOLVE: RT = 1
ⴜ
20
Mⴙ
1
ⴜ
1000
Mⴙ
1
ⴜ
45
Mⴙ
ⴜ
1
12 A
NOTE:
FIGURE 41–20 Example 2. THE TOTAL RESISTANCE (RT) MUST BE LESS THAN THE SMALLEST RESISTANCE (LESS THAN 20 ⍀ IN THIS EXAMPLE).
Each of the four examples includes solving for the following:
=
MRC
FIGURE 41–17 Another example of how to use an electronic calculator to determine the total resistance of a parallel circuit. The answer is 13.45 ohms. Notice that the effective resistance of this circuit is less than the resistance of the lowest branch (20 ohms).
ⴙ 12 ⍀
12 V
12 ⍀
12 ⍀
12 ⍀
ⴚ
FIGURE 41–18 A parallel circuit containing four 12-ohm resistors. When a circuit has more than one resistor of equal value, the total resistance can be determined by simply dividing the value of the resistance (12 ohms in this example) by the number of equalvalue resistors (4 in this example) to get 3 ohms. NOTE: Since most automotive and light-truck electrical circuits involve multiple use of the same resistance, this method is the most useful. For example, if six additional 12-ohm lights were added to a vehicle, the additional lights would represent just 2 ohms of resistance (12 Ω/6 lights 2). Therefore, 6 amperes of additional current would be drawn by the additional lights (I E/R 12 V/2 Ω 6 A).
440
CHAPTER 4 1
PARALLEL CIRCUIT EXAMPLES
Total resistance
Current flow (amperes) through each branch as well as total current flow
Voltage drop across each resistance Example 1: SEE FIGURE 41–19. In this example, the voltage of the battery is unknown and the equation to be used is E ⫽ I ⫻ R where R represents the total resistance of the circuit. Using the equation for two resistors in parallel, the total resistance is 6 ohms. R1 3 R2 12 3 12 144 RT 5 5 5 56V R1 1 R2 12 1 12 24 Placing the value of the total resistors into the equation results in a value for the battery voltage of 12 volts. EIR E2A6Ω E 12 volts
Example 2: SEE FIGURE 41–20. In this example, the value of R3 is unknown. Because the voltage (12 volts) and the current (12 A) are known, it is easier to solve for the unknown resistance by treating each branch or leg as a separate circuit. Using Kirchhoff’s law, the total current equals the total current flow
2 OHMS
4A
ⴙ 12 VOLTS
1 AMP
ⴚ
+ VOLTAGE = ?
3 AMPS
R1 12 ⍀
R2 12 ⍀
R3 12 ⍀
R4 12 ⍀
2 AMPS 6 OHMS
3 OHMS
FIGURE 41–23 A series-parallel circuit.
–
TYPE 2 HEADLAMP (HIGH AND LOW BEAM) TYPE 1 HEADLAMP (HIGH BEAM)
4A
FIGURE 41–21 Example 3. ?A
GROUND
+ R1
12 VOLTS
8 ⍀ R2
8 ⍀ R3
4⍀
–
HEADLAMP DIMMER SWITCH
HEADLAMP SWITCH
TO POWER SOURCE (BATTERY)
?A
FIGURE 41–22 Example 4. through each branch. The current flow through R1 is 3 A (I ⫽ E/R ⫽ 12 V/4 Ω ⫽ 3 A) and the current flow through R2 is 6 A (I ⫽ E/R ⫽ 12 V/2 Ω ⫽ 6 A). Therefore, the total current through the two known branches equals 9 A (3 A ⫹ 6 A ⫽ 9 A). Because there are 12 A leaving and returning to the battery, the current flow through R3 must be 3 A (12 A ⫺ 9 A ⫽ 3 A). The resistance must therefore be 4 Ω because the current through the unknown resistance is 3 A (I ⫽ E/R ⫽ 12 V/4 Ω ⫽ 3 A).
HIGH BEAM INDICATOR LAMP
FIGURE 41–24 This complete headlight circuit with all bulbs and switches is a series-parallel circuit. The total resistance of this parallel circuit containing two 8-ohm resistors and one 4-ohm resistor is 2 ohms. (Two 8 ohm resistors in parallel equals one four ohm. Then you have two four ohm resistors in parallel which equals 2 Ohms) The current flow from the battery is then calculated to be 6 A. I E/R 12 V/2 Ω 6 A
Example 3: SEE FIGURE 41–21. In this example, the voltage of the battery is unknown. The equation to solve for voltage according to Ohm’s law is:
SERIES-PARALLEL CIRCUITS
EIR The R in this equation refers to the total resistance. Because there are four resistors of equal value, the total can be determined by the equation: RTotal Value of Resistors/Number of Equal Resistors 12 Ω/4 3 Ω Inserting the value of the total resistance of the parallel circuit (3 Ω) into Ohm’s law results in a battery voltage of 12 V. E4A3Ω
Series-parallel circuits are a combination of series and parallel segments in one complex circuit. A series-parallel circuit is also called a compound or a combination circuit. Many automotive circuits include sections that are in parallel and in series. A series-parallel circuit includes both parallel loads or resistances, plus additional loads or resistances that are electrically connected in series. There are two basic types of series-parallel circuits.
A circuit where the load is in series with other loads in parallel. SEE FIGURE 41–23. An example of this type of seriesparallel circuit is a dash light dimming circuit. The variable resistor is used to limit current flow to the dash light bulbs, which are wired in parallel.
A circuit where a parallel circuit contains resistors or loads which are in series with one or more branches. A headlight and starter circuit is an example of this type of series-parallel circuit. A headlight switch is usually connected in series with a dimmer switch and in parallel with the dash light dimmer resistors. The headlights are also connected in parallel along with the taillights and side marker lights. SEE FIGURE 41–24.
E 12 V
Example: 4 SEE FIGURE 41–22. The unknown is the amount of current in the circuit. The Ohm’s law equation for determining current is: I E/R The R represents the total resistance. Because there are two equal resistances (8 Ω), these two can be replaced by one resistance of 4 Ω (RTotal⫽ Value/Number ⫽ 8 Ω/2 ⫻ 4 Ω).
SE RI E S, PARAL L E L , AN D SE RI E S-PARAL L EL C IRC U IT S
441
3A
?⍀
3A
R1 R1
+
4⍀
+ R3
12 VOLT
8⍀
– R2
4⍀
R1 + R 2 = 8 ⍀
3A
FIGURE 41–25 Solving a series-parallel circuit problem.
SERIES-PARALLEL CIRCUIT FAULTS If a conventional parallel circuit, such as a taillight circuit, had an electrical fault that increased the resistance in one branch of the circuit, then the amount of current flow through that one branch will be reduced. The added resistance, due to corrosion or other similar cause, would create a voltage drop. As a result of this drop in voltage, a lower voltage would be applied and the bulb in the taillight would be dimmer than normal. Because the brightness of the bulb depends on the voltage and current applied, the lower voltage and current would cause the bulb to be dimmer than normal. If, however, the added resistance occurred in a part of the circuit that fed both taillights, then both taillights would be dimmer than normal. In this case, the added resistance created a series-parallel circuit that was originally just a simple parallel circuit.
4⍀
R2
12 VOLTS
4⍀
R3
–
3A
FIGURE 41–26 Example 1.
3A
R1
4⍀
R3
4⍀
R2
4⍀
R4
4⍀
+ VOLTS = ? –
3A
FIGURE 41–27 Example 2.
SOLVING SERIES-PARALLEL CIRCUIT PROBLEMS The key to solving series-parallel circuit problems is to combine or simplify as much as possible. For example, if there are two loads or resistances in series within a parallel branch or leg, then the circuit can be made simpler if the two are first added together before attempting to solve the parallel section. SEE FIGURE 41–25.
The total resistance of the circuit is therefore 4 ohms, and the value of the unknown can be determined by subtracting the value of the two resistors that are connected in parallel. The parallel branch resistance is 2 Ω. 434 16 RT 5 5 52V 414 8 The value of the unknown resistance is therefore 2 Ω. Total R 4 Ω 2 Ω 2 Ω
Example 2:
SERIES-PARALLEL CIRCUIT EXAMPLES Each of the four examples includes solving for the following.
Total resistance
Current flow (amperes) through each branch, as well as total current flow
Voltage drop across each resistance
SEE FIGURE 41–27. The unknown unit in this circuit is the voltage of the battery. The Ohm’s law equation is: EIR Before solving the problem, the total resistance must be determined. Because each branch contains two 4-ohm resistors in series, the value in each branch can be added to help simplify the circuit. By adding the resistors in each branch together, the parallel circuit now consists of two 8-ohm resistors. RT 5
R1 3 R2 64 838 5 54V 5 R1 1 R2 818 16
Example 1: SEE FIGURE 41–26. The unknown resistor is in series with the other two resistances, which are connected in parallel. The Ohm’s law equation to determine resistance is: R E/I 12 V/3 A 4 Ω
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Inserting the value for the total resistance into the Ohm’s law equation results in a value of 12 volts for the battery voltage. EIR E3A4Ω E 12 volts
?A
2⍀
4⍀
R1
R3
4A
?⍀
4⍀
R1
R2
+
+ R2
12 VOLTS
8⍀
R4
4⍀
12 VOLTS
R3
4 ⍀ R4
8⍀
4⍀
R5
–
–
4A
?A
FIGURE 41–29 Example 4.
FIGURE 41–28 Example 3.
Example 4: Example 3: SEE FIGURE 41–28. In this example, the total current through the circuit is unknown. The Ohm’s law equation to solve for it is: I E/R The total resistance of the parallel circuit must be determined before the equation can be used to solve for current (amperes). To solve for total resistance, the circuit can first be simplified by adding R3 and R4 together because these two resistors are in series in the same branch of the parallel circuit. To simplify even more, the resulting parallel section of the circuit, now containing two 8-ohm resistors in parallel, can be replaced with one 4-ohm resistor. RT 5
R1 3 R2 838 64 5 5 54V R1 1 R2 818 16
With the parallel branches now reduced to just one 4-ohm resistor, this can be added to the 2-ohm (R1) resistor because it is in series, creating a total circuit resistance of 6 ohms. Now the current flow can be determined from Ohm’s law: I E/R 12 V/6 Ω 2 A
SEE FIGURE 41–29. In this example, the value of resistor R1 is unknown. Using Ohm’s law, the total resistance of the circuit is 3 ohms. R E/I 12 V/4 A 3 Ω However, knowing the total resistance is not enough to determine the value of R1. To simplify the circuit, R2 and R5 can combine to create a parallel branch resistance value of 8 ohms because they are in series. To simplify even further, the two 8-ohm branches can be reduced to one branch of 4 ohms. RT 5
R1 3 R2 838 64 5 5 54V R1 1 R2 818 16
Now the circuit has been simplified to one resistor in series (R1) with two branches with 4 ohms in each branch. These two branches can be reduced to the equal of one 2-ohm resistor. RT 5
R1 3 R2 434 16 5 5 52V R1 1 R2 414 8
Now the circuit includes just one 2-ohm resistor plus the unknown R1. Because the total resistance is 3 ohms, the value of R1 must be 1 ohm. 3Ω2Ω1Ω
REVIEW QUESTIONS 1. What is Kirchhoff’s voltage law? 2. What would current (amperes) do if the voltage were doubled in a circuit?
6. Why are parallel circuits (instead of series circuits) used in most automotive applications? 7. What does Kirchhoff’s current law state?
3. What would current (amperes) do if the resistance in the circuit were doubled?
8. What would be the effect of an open circuit in one leg of a parallel portion of a series-parallel circuit?
4. What is the formula for voltage drop?
9. What would be the effect of an open circuit in a series portion of a series-parallel circuit?
5. Why is the total resistance of a parallel circuit less than the smallest resistance?
CHAPTER QUIZ 1. The amperage in a series circuit is ______________. a. The same anywhere in the circuit b. Varies in the circuit due to the different resistances c. High at the beginning of the circuit and decreases as the current flows through the resistance d. Always less returning to the battery than leaving the battery
2. The sum of the voltage drops in a series circuit equals the ______________. a. Amperage b. Resistance c. Source voltage d. Wattage
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3. If the resistance and the voltage are known, what is the formula for finding the current (amperes)? a. E ⫽ I ⫻ R c. R ⫽ E ⫻ I b. I ⫽ E ⫻ R d. I ⫽ E/R 4. A series circuit has three resistors of 4 ohms each. The voltage drop across each resistor is 4 volts. Technician A says that the source voltage is 12 volts. Technician B says that the total resistance is 18 ohms. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 5. If a 12-volt battery is connected to a series circuit with three resistors of 2 ohms, 4 ohms, and 6 ohms, how much current will flow through the circuit? a. 1 amp c. 3 amp b. 2 amp d. 4 amp 6. A series circuit has two 10-ohm bulbs. A third bulb is added in series. Technician A says that the three bulbs will be dimmer than when only two bulbs were in the circuit. Technician B says that the current in the circuit will increase. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 7. Technician A says that the sum of the voltage drops in a series circuit should equal the source voltage. Technician B says that the current (amperes) varies depending on the value of the resistance in a series circuit. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
chapter
42
8. Two bulbs are connected in parallel to a 12-volt battery. One bulb has a resistance of 6 ohms and the other bulb has a resistance of 2 ohms. Technician A says that only the 2-ohm bulb will light because all of the current will flow through the path with the least resistance and no current will flow through the 6-ohm bulb. Technician B says that the 6-ohm bulb will be dimmer than the 2-ohm bulb. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 9. Calculate the total resistance and current in a parallel circuit with three resistors of 4 Ω, 8 Ω, and 16 Ω, using any one of the five methods (calculator suggested). What is the total resistance and current? a. 27 ohms (0.4 ampere) b. 14 ohms (0.8 ampere) c. 4 ohms (3.0 amperes) d. 2.3 ohms (5.3 amperes) 10. A vehicle has four parking lights all connected in parallel and one of the bulbs burns out. Technician A says that this could cause the parking light circuit fuse to blow (open). Technician B says that it would decrease the current in the circuit. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
CIRCUIT TESTERS AND DIGITAL METERS
OBJECTIVES: After studying Chapter 42, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic System Diagnosis). • Discuss how to safely use a fused jumper wire, a test light, and a logic probe. • Explain how to set up and use a digital meter to read voltage, resistance, and current. • Explain meter terms and readings. • Interpret meter readings and compare to factory specifications. • Discuss how to properly and safely use meters. KEY TERMS: AC/DC clamp-on DMM 450 • Continuity light 445 • DMM 446 • DVOM 446 • High-impedance test meter 446 • IEC 454 • Inductive ammeter 450 • Kilo (k) 451 • LED test light 445 • Logic probe 446 • Mega (M) 451 • Meter accuracy 455 • Meter resolution 454 • Milli (m) 451 • OL 448 • RMS 453 • Test light 445
Alligator clip ends. Alligator clips on the ends allow the fused jumper wire to be clipped to a ground or power source while the other end is attached to the power side or ground side of the unit being tested.
Good-quality insulated wire. Most purchased jumper wire is about 14 gauge stranded copper wire with a flexible rubberized insulation to allow it to move easily even in cold weather.
FUSED JUMPER WIRE DEFINITION
A fused jumper wire is used to check a circuit by bypassing the switch or to provide a power or ground to a component. A fused jumper wire, also called a test lead, can be purchased or made by the service technician. SEE FIGURE 42–1. It should include the following features.
Fused. A typical fused jumper wire has a blade-type fuse that can be easily replaced. A 10 ampere fuse (red color) is often the value used.
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USES OF A FUSED JUMPER WIRE A fused jumper wire can be used to help diagnose a component or circuit by performing the following procedures.
BODY GROUND POINT
12-VOLT TEST LIGHT
FIGURE 42–2 A 12 volt test light is attached to a good ground while probing for power.
BATTERY
CHASSIS GROUND
FIGURE 42–1 A technician-made fused jumper lead, which is equipped with a red 10 ampere fuse. This fused jumper wire uses terminals for testing circuits at a connector instead of alligator clips.
Supply power or ground. If a component, such as a horn, does not work, a fused jumper wire can be used to supply a temporary power and/or ground. Start by unplugging the electrical connector from the device and connect a fused jumper lead to the power terminal. Another fused jumper wire may be needed to provide the ground. If the unit works, the problem is in the power side or ground side circuit.
CAUTION: Never use a fused jumper wire to bypass any resistance or load in the circuit. The increased current flow could damage the wiring and could blow the fuse on the jumper lead.
IGNITION SWITCH
ACCIDENTAL OPEN
FIGURE 42–3 A test light can be used to locate an open in a circuit. Note that the test light is grounded at a different location than the circuit itself.
TEST LIGHTS NONPOWERED TEST LIGHT
A 12 volt test light is one of the simplest testers that can be used to detect electricity. A test light is simply a light bulb with a probe and a ground wire attached. SEE FIGURE 42–2. It is used to detect battery voltage potential at various test points. Battery voltage cannot be seen or felt, and can be detected only with test equipment. The ground clip is connected to a clean ground on either the negative terminal of the battery or a clean metal part of the body and the probe touched to terminals or components. If the test light comes on, this indicates that voltage is available. SEE FIGURE 42–3. A purchased test light could be labeled a “12 volt test light.” Do not purchase a test light designed for household current (110 or 220 volts), as it will not light with 12 to 14 volts.
USES OF A 12 VOLT TEST LIGHT
A 12 volt test light can be
CONTINUITY TEST LIGHTS A continuity light is similar to a test light but includes a battery for self-power. A continuity light illuminates whenever it is connected to both ends of a wire that has continuity or is not broken. SEE FIGURE 42–4. CAUTION: The use of a self-powered (continuity) test light is not recommended on any electronic circuit, because a continuity light contains a battery and applies voltage; therefore, it may harm delicate electronic components.
HIGH-IMPEDANCE TEST LIGHT A high-impedance test light has a high internal resistance and therefore draws very low current in order to light. High-impedance test lights are safe to use on computer circuits because they will not affect the circuit current in the same way as conventional 12 volt test lights when connected to a circuit. There are two types of high-impedance test lights.
Some test lights use an electronic circuit to limit the current flow, to avoid causing damage to electronic devices.
An LED test light uses a light-emitting diode (LED) instead of a standard automotive bulb for a visual indication of voltage. An LED test light requires only about 25 milliamperes (0.025 ampere) to light; therefore, it can be used on electronic circuits as well as on standard circuits.
used to check the following:
Electrical power. If the test light lights, then there is power available. It will not, however, indicate the voltage level or if there is enough current available to operate an electrical load. This indicates only that there is enough voltage and current to light the test light (about 0.25 A).
Grounds. A test light can be used to check for grounds by attaching the clip of the test light to the positive terminal of the battery or any 12 volt electrical terminal. The tip of the test light can then be used to touch the ground wire. If there is a ground connection, the test light will light.
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BATTERY IN HANDLE
LIGHT IN TIP
NEGATIVE (BLACK)
FIGURE 42–4 A continuity light should not be used on computer circuits because the applied voltage can damage delicate electronic components or circuits.
RED, GREEN, OR YELLOW
LED
CATHODE (–)
2-FOOT WIRE LEAD
POSITIVE (RED)
HOUSING CAN BE A “CLICKER” STYLE BALL-POINT PEN. REMOVE INK INSERT AND REPLACE WITH LED, RESISTOR, AND WIRING ANODE (ⴙ) 470-⍀ RESISTOR (1/2 WATT)
ALLIGATOR CLIP
NAIL OR PROBE
FIGURE 42–5 An LED test light can be easily made using low cost components and an old ink pen. With the 470 ohm resistor in series with the LED, this tester only draws 0.025 ampere (25 milliamperes) from the circuit being tested. This low current draw helps assure the technician that the circuit or component being tested will not be damaged by excessive current flow.
ⴙ
ⴚ
BATTERY
AUXILIARY POWER LEAD
FIGURE 42–6 A logic probe connected to the vehicle battery. When the tip probe is connected to a circuit, it can check for power, ground, or a pulse. probing connectors or component terminals. A sound (usually a beep) is heard when the probe tip is touched to a changing voltage source. The changing voltage also usually lights the pulse light on the logic probe. Therefore, the probe can be used to check components such as:
Pickup coils
Hall-effect sensors
Magnetic sensors
SEE FIGURE 42–5 for construction details for a homemade LED test light.
DIGITAL MULTIMETERS LOGIC PROBE PURPOSE AND FUNCTION
A logic probe is an electronic device that lights up a red (usually) LED if the probe is touched to battery voltage. If the probe is touched to ground, a green (usually) LED lights. SEE FIGURE 42–6. A logic probe can “sense” the difference between high- and low-voltage levels, which explains the name logic.
A typical logic probe can also light another light (often amber color) when a change in voltage levels occurs.
Some logic probes will flash the red light when a pulsing voltage signal is detected.
Some will flash the green light when a pulsing ground signal is detected.
This feature is helpful when checking for a variable voltage output from a computer or ignition sensor.
USING A LOGIC PROBE A logic probe must first be connected to a power and ground source such as the vehicle battery. This connection powers the probe and gives it a reference low (ground). Most logic probes also make a distinctive sound for each highand low-voltage level. This makes troubleshooting easier when
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TERMINOLOGY
Digital multimeter (DMM) and digital voltohm-meter (DVOM) are terms commonly used for electronic highimpedance test meters. High impedance means that the electronic internal resistance of the meter is high enough to prevent excessive current draw from any circuit being tested. Most meters today have a minimum of 10 million ohms (10 megohms) of resistance. This high internal resistance between the meter leads is present only when measuring volts. The high resistance in the meter itself reduces the amount of current flowing through the meter when it is being used to measure voltage, leading to more accurate test results because the meter does not change the load on the circuit. High-impedance meters are required for measuring computer circuits. CAUTION: Analog (needle-type) meters are almost always lower than 10 megohms and should not be used to measure any computer or electronic circuit. Connecting an analog meter to a computer circuit could damage the computer or other electronic modules.
A high-impedance meter can be used to measure any automotive circuit within the ranges of the meter. SEE FIGURE 42–7. The common abbreviations for the units that many meters can measure are often confusing. SEE CHART 42–1 for the most commonly used symbols and their meanings.
FIGURE 42–7 Typical digital multimeter. The black meter lead always is placed in the COM terminal. The red meter test lead should be in the volt-ohm terminal except when measuring current in amperes.
DISPLAY HOLD
FLUKE 87
TRUE RMS MULTIMETER AC DC
AUTO 100ms RECORD MAX MIN AVG
MANUAL RANGE
DIGITAL DISPLAY
μm V A %
M k Ω Hz
MIN/MAX RECORDING
0
1
2
3
4
5
6
8
7
9
0
4000 mV
TOGGLE BUTTON MIN MAX
BACKLIGHT
RANGE
HOLD
CONTINUITY BEEPER RELATIVE READINGS
Hz
REL
FREQUENCY AND DUTY CYCLE
PEAK MIN MAX
Ω mV
ROTARY SWITCH
= DIODE TEST mA A
V
VOLTS, OHMS, DIODE CHECK INPUT TERMINAL COMMON TERMINAL
μA
V
μA
MEANING
AC
Alternating current or voltage
DC
Direct current or voltage
V
Volts
mV
Millivolts (1/1,000 volts)
A
Ampere (amps), current
mA
Milliampere (1/1,000 amps)
%
Percent (for duty cycle readings only)
Ω
Ohms, resistance
kΩ
Kilohm (1,000 ohms), resistance
MΩ
Megohm (1,000,000 ohms), resistance
Hz
Hertz (cycles per second), frequency
kHz
Kilohertz (1,000 cycles/sec.), frequency
Ms
Milliseconds (1/1,000 sec.) for pulse width measurements
A
mA pA
COM
VΩ
V = DC VOLTS V
400 mA MAX FUSED
= AC VOLTS
1000 V MAX
!
FIGURE 42–8 Typical digital multimeter (DMM) set to read DC volts.
DC volts (DCV). This setting is the most common for automotive use. Use this setting to measure battery voltage and voltage to all lighting and accessory circuits.
AC volts (ACV). This setting is used to check for unwanted AC voltage from alternators and some sensors.
Range. The range is automatically set for most meters but can be manually ranged if needed.
CHART 42–1 Common symbols and abbreviations used on digital meters.
= AC OR DC MICROAMPERES
mV = DC MILLIVOLTS
10 A MAX FUSED
SYMBOL
= AC OR DC AMPERES MILLIAMPERES
Ω = OHMS (RESISTANCE) OFF
MILLIAMP/MICROAMP INPUT TERMINAL AMPERES INPUT TERMINAL
= CAPACITANCE mA A
SEE FIGURES 42–8 AND 42–9.
MEASURING VOLTAGE
A voltmeter measures the pressure or potential of electricity in units of volts. A voltmeter is connected to a circuit in parallel. Voltage can be measured by selecting either AC or DC volts.
MEASURING RESISTANCE
An ohmmeter measures the resistance in ohms of a component or circuit section when no current is flowing through the circuit. An ohmmeter contains a battery (or other
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DIGITAL MULTIMETER DC
AUTO
3.865
V
0 1 2 3 4 5 6 7 8
9 0
4
BECAUSE THE SIGNAL READING IS BELOW 4 VOLTS, THE METER AUTORANGES TO THE 4-VOLT SCALE. IN THE 4-VOLT SCALE, THIS METER PROVIDES THREE DECIMAL PLACES.
FIGURE 42–10 Using a digital multimeter set to read ohms (Ω) to test this light bulb. The meter reads the resistance of the filament.
(a)
?
FREQUENTLY ASKED QUESTION
How Much Voltage Does an Ohmmeter Apply?
DIGITAL MULTIMETER
Most digital meters that are set to measure ohms (resistance) apply 0.3 to 1 volt to the component being measured. The voltage comes from the meter itself to measure the resistance. Two things are important to remember about an ohmmeter.
DC
AUTO
04.65
0 1 2 3 4 5 6 7 8
V 9 0
40
1. The component or circuit must be disconnected from any electrical circuit while the resistance is being measured. 2. Because the meter itself applies a voltage (even though it is relatively low), a meter set to measure ohms can damage electronic circuits. Computer or electronic chips can be easily damaged if subjected to only a few milliamperes of current, similar to the amount an ohmmeter applies when a resistance measurement is being performed.
WHEN THE VOLTAGE EXCEEDED 4 VOLTS, THE METER AUTORANGES INTO THE 40-VOLT SCALE. THE DECIMAL POINT MOVES ONE PLACE TO THE RIGHT LEAVING ONLY TWO DECIMAL PLACES. (b)
FIGURE 42–9 A typical autoranging digital multimeter automatically selects the proper scale to read the voltage being tested. The scale selected is usually displayed on the meter face. (a) Note that the display indicates “4,” meaning that this range can read up to 4 volts. (b) The range is now set to the 40 volt scale, meaning that the meter can read up to 40 volts on the scale. Any reading above this level will cause the meter to reset to a higher scale. If not set on autoranging, the meter display would indicate OL if a reading exceeds the limit of the scale selected. power source) and is connected in series with the component or wire being measured. When the leads are connected to a component, current flows through the test leads and the difference in voltage (voltage drop) between the leads is measured as resistance. Note the following facts about using an ohmmeter.
Zero ohms on the scale means that there is no resistance between the test leads, thus indicating continuity or a continuous path for the current to flow in a closed circuit.
Infinity means no connection, as in an open circuit.
Ohmmeters have no required polarity even though red and black test leads are used for resistance measurement.
CAUTION: The circuit must be electrically open with no current flowing when using an ohmmeter. If current is flowing when an ohmmeter is connected, the reading will be incorrect and the meter can be destroyed. Different meters have different ways of indicating infinity resistance, or a reading higher than the scale allows. Examples of an over limit display include:
OL, meaning over limit or overload
Flashing or solid number 1
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Flashing or solid number 3 on the left side of the display
Flashing or solid number 4 on the display.
Check the meter instructions for the exact display used to indicate an open circuit or over range reading. SEE FIGURES 42–10 AND 42–11. To summarize, open and zero readings are as follows: 0.00 Ω ⫽ Zero resistance (component or circuit has continuity) OL ⫽ An open circuit or reading is higher than the scale selected (no current flows)
MEASURING AMPERES
An ammeter measures the flow of current through a complete circuit in units of amperes. The ammeter has to be installed in the circuit (in series) so that it can measure all the current flow in that circuit, just as a water flow meter would measure the amount of water flow (cubic feet per minute, for example). SEE FIGURE 42–12. CAUTION: An ammeter must be installed in series with the circuit to measure the current flow in the circuit. If a meter set to read amperes is connected in parallel, such as across a battery, the meter or the leads may be destroyed, or the fuse will blow, by the current available across the battery. Some digital multimeters (DMMs) beep if the unit selection does not match the test lead connection on the meter. However, in a noisy shop, this beep sound may be inaudible.
FIGURE 42–11 Many digital multimeters can have the display indicate zero to compensate for test lead resistance. (1) Connect leads in the V Ω and COM meter terminals. (2) Select the Ω scale. (3) Touch the two meter leads together. (4) Push the “zero” or “relative” button on the meter. (5) The meter display will now indicate zero ohms of resistance.
DIGITAL MULTIMETER
DIGITAL MULTIMETER
000.0
000.1
0 1 2 3 4 5 6 7 8
5
AUTO
AUTO
0 1 2 3 4 5 6 7 8
9 0
9 0
4 ZERO
2
mV
mV mA A
V
A
V
A
V
mA A
V
1 A
mA A
COM
mA A
V
COM
V
3 BLACK
AMMETER
HORN WIRE
BLACK
RED
RED
TECH TIP
DIGITAL MULTIMETER RECORD
MAX MIN
5.60A 1 2 03 4 5 6 7 8
% HZ
9 0
MIN MAX
HZ
mV mA A
V
A
V
A
mA A
COM
V
HORN
FIGURE 42–12 Measuring the current flow required by a horn requires that the ammeter be connected to the circuit in series and the horn button be depressed by an assistant.
Digital meters require that the meter leads be moved to the ammeter terminals. Most digital meters have an ampere scale that can accommodate a maximum of 10 amperes. See the Tech Tip, “Fuse Your Meter Leads!”
Fuse Your Meter Leads! Most digital meters include an ammeter capability. When reading amperes, the leads of the meter must be changed from volts or ohms (V or Ω) to amperes (A), milliamperes (mA), or microamperes (μA). A common problem may then occur the next time voltage is measured. Although the technician may switch the selector to read volts, often the leads are not switched back to the volt or ohm position. Because the ammeter lead position results in zero ohms of resistance to current flow through the meter, the meter or the fuse inside the meter will be destroyed if the meter is connected to a battery. Many meter fuses are expensive and difficult to find. To avoid this problem, simply solder an inline 10 ampere blade-fuse holder into one meter lead. SEE FIGURE 42–13. Do not think that this technique is for beginners only. Experienced technicians often get in a hurry and forget to switch the lead. A blade fuse is faster, easier, and less expensive to replace than a meter fuse or the meter itself. Also, if the soldering is done properly, the addition of an inline fuse holder and fuse does not increase the resistance of the meter leads. All meter leads have some resistance. If the meter is measuring very low resistance, touch the two leads together and read the resistance (usually no more than 0.2 ohm). Simply subtract the resistance of the leads from the resistance of the component being measured.
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FIGURE 42–13 Note the blade-type fuse holder soldered in series with one of the meter leads. A 10 ampere fuse helps protect the internal meter fuse (if equipped) and the meter itself from damage that may result from excessive current flow if accidentally used incorrectly.
FIGURE 42–15 A typical mini clamp-on-type digital multimeter. This meter is capable of measuring alternating current (AC) and direct current (DC) without requiring that the circuit be disconnected to install the meter in series. The jaws are simply placed over the wire and current flow through the circuit is displayed.
This means that the meter probe surrounds the wire(s) carrying the current and measures the strength of the magnetic field that surrounds any conductor carrying a current.
AC/DC CLAMP-ON DIGITAL MULTIMETERS
An AC/DC clamp-on digital multimeter (DMM) is a useful meter for automotive diagnostic work. SEE FIGURE 42–15. The major advantage of the clamp-on-type meter is that there is no need to break the circuit to measure current (amperes). Simply clamp the jaws of the meter around the power lead(s) or ground lead(s) of the component being measured and read the display. Most clamp-on meters can also measure alternating current, which is helpful in the diagnosis of an alternator problem. Volts, ohms, frequency, and temperature can also be measured with the typical clamp-on DMM, but use conventional meter leads. The inductive clamp is only used to measure amperes.
FIGURE 42–14 An inductive ammeter clamp is used with all starting and charging testers to measure the current flow through the battery cables.
?
DIODE CHECK, PULSE WIDTH, AND FREQUENCY
FREQUENTLY ASKED QUESTION
What Does “CE” Mean on Many Meters? The “CE” means that the meter meets the newest European Standards and the letters CE stands for a French term for “Conformite’ Europeenne” meaning European Conformity in French.
DIODE CHECK Diode check is a meter function that can be used to check diodes including light-emitting diodes (LEDs). The meter is able to text diodes by way of the following:
The meter applies roughly a 3 volt DC signal to the text leads.
The voltage is high enough to cause a diode to work and the meter will display: 1. 0.4 to 0.7 volt when testing silicon diodes such as found in alternators 2. 1.5 to 2.3 volts when testing LEDs such as found in some lighting applications
INDUCTIVE AMMETERS OPERATION
Inductive ammeters do not make physical contact with the circuit. They measure the strength of the magnetic field surrounding the wire carrying the current, and use a Hall-effect sensor to measure current. The Hall-effect sensor detects the strength of the magnetic field that surrounds the wire carrying an electrical current. SEE FIGURE 42–14.
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PULSE WIDTH
Pulse width is the amount of time in a percentage that a signal is on compared to being off.
100% pulse width indicates that a device is being commanded on all of the time.
50% pulse width indicates that a device is being commanded on half of the time.
DIGITAL MULTIMETER AUTO
3.124 20 2 4 6 8 30 2 4 6
KΩ 8 40
THE SYMBOL ON THE RIGHT SIDE OF THE DISPLAY INDICATES WHAT RANGE THE METER HAS BEEN SET TO READ.
Ω = OHMS IF THE ONLY SYMBOL ON THE DISPLAY IS THE OHMS SYMBOL, THE READING ON THE DISPLAY IS EXACTLY THE RESISTANCE IN OHMS.
KΩ = KILOHMS = OHMS TIMES 1000 A "K" IN FRONT OF THE OHMS SYMBOL MEANS "KILOHMS"; THE READING ON THE DISPLAY IS IN KILOHMS. YOU HAVE TO MULTIPLY THE READING ON THE DISPLAY BY 1000 TO GET THE RESISTANCE IN OHMS.
MΩ = MEGOHMS = OHMS TIMES 1,000,000
FIGURE 42–16 Typical digital multimeter showing OL (over limit) on the readout with the ohms (Ω) unit selected. This usually means that the unit being measured is open (infinity resistance) and has no continuity. TECH TIP
A "M" IN FRONT OF THE OHMS SYMBOL MEANS "MEGOHMS"; THE READING ON THE DISPLAY IS IN MEGOHMS. YOU HAVE TO MULTIPLY THE READING ON THE DISPLAY BY 1,000,000 TO GET THE RESISTANCE IN OHMS.
FIGURE 42–17 Always look at the meter display when a measurement is being made, especially if using an autoranging meter.
Over Limit Display Does Not Mean the Meter Is Reading “Nothing” The meaning of the over limit display on a digital meter often confuses beginning technicians. When asked what the meter is reading when an over limit (OL) is displayed on the meter face, the response is often, “Nothing.” Many meters indicate over limit or over load, which simply means that the reading is over the maximum that can be displayed for the selected range. For example, the meter will display OL if 12 volts are being measured but the meter has been set to read a maximum of 4 volts. Autoranging meters adjust the range to match what is being measured. Here OL means a value higher than the meter can read (unlikely on the voltage scale for automobile usage), or infinity when measuring resistance (ohms). Therefore, OL means infinity when measuring resistance or an open circuit is being indicated. The meter will read 00.0 if the resistance is zero, so “nothing” in this case indicates continuity (zero resistance), whereas OL indicates infinity resistance. Therefore, when talking with another technician about a meter reading, make sure you know exactly what the reading on the face of the meter means. Also be sure that you are connecting the meter leads correctly. SEE FIGURE 42–16.
Frequency measurements are used when checking the following:
Mass airflow (MAF) sensors for proper operation
Ignition primary pulse signals when diagnosing a no-start condition
Checking a wheel speed sensor
ELECTRICAL UNIT PREFIXES DEFINITIONS
Electrical units are measured in numbers such as 12 volts, 150 amperes, and 470 ohms. Large units over 1,000 may be expressed in kilo units. Kilo (k) means 1,000. SEE FIGURE 42–17. 4,700 ohms ⫽ 4.7 kilohms (kΩ) If the value is over 1 million (1,000,000), then the prefix mega (M) is often used. For example: 1,100,000 volts ⫽ 1.1 megavolts (MV) 4,700,000 ohms ⫽ 4.7 megohms (MΩ) Sometimes a circuit conducts so little current that a smaller unit of measure is required. Small units of measure expressed in 1/1,000 are prefixed by milli (m). To summarize: mega (M) ⫽ 1,000,000 (decimal point six places to the right ⫽ 1,000,000) kilo (k) ⫽ 1,000 (decimal point three places to the right ⫽ 1,000)
25% pulse width indicates that a device is being commanded on just 25% of the time.
Pulse width is used to measure the on time for fuel injectors and other computer-controlled solenoid and devices.
milli (m) ⫽ 1/1,000 (decimal point three places to the left ⫽ 0.001) HINT: Lowercase m equals a small unit (milli), whereas a capital M represents a large unit (mega).
SEE CHART 42–2.
FREQUENCY
Frequency is a measure of how many times per second a signal changes. Frequency is measured in a unit called hertz, formerly termed “cycles per second.”
PREFIXES The prefixes can be confusing because most digital meters can express values in more than one unit, especially if the C I RC U I T T E ST E RS AN D D I G IT A L M ET ERS
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TO/ FROM
MEGA
KILO
BASE
MILLI
Mega
0 places
3 places to the right
6 places to the right
9 places to the right
Kilo
3 places to the left
0 places
3 places to the right
6 places to the right
Base
6 places to the left
3 places to the left
0 places
3 places to the right
Milli
9 places to the left
6 places to the left
3 places to the left
0 places
the proper scale for the anticipated reading. For example, if a 12 volt battery is being measured, select a meter reading range that is higher than the voltage but not too high. A 20 or 30 volt range will accurately show the voltage of a 12 volt battery. If a 1,000 volt scale is selected, a 12 volt reading may not be accurate. STEP 2
CHART 42–2 A conversion chart showing the decimal point location for the various prefixes.
CAUTION: If the meter leads are inserted into ammeter terminals, even though the selector is set to volts, the meter may be damaged or an internal fuse may blow if the test leads touch both terminals of a battery.
TECH TIP Think of Money
STEP 3
Measure the component being tested. Carefully note the decimal point and the unit on the face of the meter. • Meter lead connections. If the meter leads are connected to a battery backwards (red to the battery negative, for example), the display will still show the correct reading, but a negative sign (⫺) will be displayed in front of the number. The correct polarity is not important when measuring resistance (ohms) except where indicated, such as measuring a diode. • Autorange. Many meters automatically default to the autorange position and the meter will display the value in the most readable scale. The meter can be manually ranged to select other levels or to lock in a scale for a value that is constantly changing. If a 12 volt battery is measured with an autoranging meter, the correct reading of 12.0 is given. “AUTO” and “V” should show on the face of the meter. For example, if a meter is manually set to the 2 kilohm scale, the highest that the meter will read is 2,000 ohms. If the reading is over 2,000 ohms, the meter will display OL. SEE CHART 42–3.
STEP 4
Interpret the reading. This is especially difficult on autoranging meters, where the meter itself selects the proper scale. The following are two examples of different readings.
Digital meter displays can often be confusing. The display for a battery measured as 12 1/2 volts would be 12.50 V, just as $12.50 is 12 dollars and 50 cents. A 1/2 volt reading on a digital meter will be displayed as 0.50 V, just as $0.50 is half of a dollar. It is more confusing when low values are displayed. For example, if a voltage reading is 0.063 volt, an autoranging meter will display 63 millivolts (63 mV), or 63/1,000 of a volt, or $63 of $1,000. (It takes 1,000 mV to equal 1 volt.) Think of millivolts as one-tenth of a cent, with 1 volt being $1.00. Therefore, 630 millivolts are equal to $0.63 of $1.00 (630 tenths of a cent, or 63 cents). To avoid confusion, try to manually range the meter to read base units (whole volts). If the meter is ranged to base unit volts, 63 millivolts would be displayed as 0.063 or maybe just 0.06, depending on the display capabilities of the meter.
meter is autoranging. For example, an ammeter reading may show 36.7 mA on autoranging. When the scale is changed to amperes (“A” in the window of the display), the number displayed will be 0.037 A. Note that the resolution of the value is reduced. HINT: Always check the face of the meter display for the unit being measured. To best understand what is being displayed on the face of a digital meter, select a manual scale and move the selector until whole units appear, such as “A” for amperes instead of “mA” for milliamperes.
HOW TO READ DIGITAL METERS STEPS TO FOLLOW Getting to know and use a digital meter takes time and practice. The first step is to read, understand, and follow all safety and operational instructions that come with the meter. Use of the meter usually involves the following steps. STEP 1
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Select the proper unit of electricity for what is being measured. This unit could be volts, ohms (resistance), or amperes (amount of current flow). If the meter is not autoranging, select
CHAPTER 4 2
Place the meter leads into the proper input terminals. • The black lead is inserted into the common (COM) terminal. This meter lead usually stays in this location for all meter functions. • The red lead is inserted into the volt, ohm, or diode check terminal usually labeled “VΩ” when voltage, resistance, or diodes are being measured. • When current flow in amperes is being measured, most digital meters require that the red test lead be inserted in the ammeter terminal, usually labeled “A” or “mA.”
Example 1: A voltage drop is being measured. The specifications indicate a maximum voltage drop of 0.2 volt. The meter reads “AUTO” and “43.6 mV.” This reading means that the voltage drop is 0.0436 volt, or 43.6 mV, which is far lower than the 0.2 volt (200 millivolts). Because the number showing on the meter face is much larger than the specifications, many beginner technicians are led to believe that the voltage drop is excessive. NOTE: Pay attention to the units displayed on the meter face and convert to whole units. Example 2: A spark plug wire is being measured. The reading should be less than 10,000 ohms for each foot in length if the wire is okay. The wire being tested is 3 ft long (maximum allowable resistance is 30,000 ohms). The meter reads “AUTO” and “14.85 kΩ.” This reading is equivalent to 14,850 ohms. NOTE: When converting from kilohms to ohms, make the decimal point a comma. Because this reading is well below the specified maximum allowable, the spark plug wire is okay.
VOLTAGE BEING MEASURED
0.01 V (10 MV)
0.150 V (150 MV)
200 mV
10.0
150.0
2V
0.100
20 V 200 V
1.5 V
10.0 V
12.0 V
120 V
OL
OL
OL
OL
0.150
1.500
OL
OL
OL
0.1
1.50
1.50
10.00
12.00
OL
00.0
01.5
01.5
10.0
12.0
120.0
00.00
00.00
000.1
00.10
00.12
0.120
10.0 mV
15.0 mV
1.50
10.0
12.0
120.0
1 KILOHM
220 KILOHMS
1 MEGOHM
OL
OL
OL
Scale Selected
2 kV Autorange
Voltmeter will display:
RESISTANCE BEING MEASURED
10 OHMS
100 OHMS
470 OHMS
10.0
100.0
OL
Scale Selected 400 ohms
Ohmmeter will display:
4 kilohms
010
100
0.470 k
1000
OL
OL
40 kilohms
00.0
0.10 k
0.47 k
1.00 k
OL
OL
400 kilohms
000.0
00.1 k
00.5 k
0.10 k
220.0 k
OL
4 megohms
00.00
0.01 M
0.05 M
00.1 M
0.22 M
1.0 M
Autorange
10.0
100.0
470.0
1.00 k
220 k
1.00 M
7.5 A
15.0 A
25.0 A
CURRENT BEING MEASURED
50 MA
150 MA
1.0 A
Scale Selected
Ammeter will display:
40 mA
OL
OL
OL
OL
OL
OL
400 mA
50.0
150
OL
OL
OL
OL
4A
0.05
0.00
1.00
OL
OL
OL
0.00
0.000
01.0
7.5
15.0
25.0
50.0 mA
150.0 mA
1.00
7.5
15.0
25.0
40 A Autorange CHART 42–3
Sample meter readings using manually set and autoranging selection on the digital meter control.
FLUKE 87
TRUE RMS MULTIMETER
6.54 0 2 4 6 8 10 2 4 6
AC V 8 20
RMS
FLUKE 87
6.54
AUTOMOTIVE METER
6.54 0 2 4 6 8 10 2 4 6
AC V 8 20
AVERAGE RESPONDING
TRUE RMS MULTIMETER
0 2 4 6 8 10 2 4 6
FLUKE 88
AC V 8 20
FLUKE 88
AUTOMOTIVE METER
4.25 0 2 4 6 8 10 2 4 6
AC V 8 20
FIGURE 42–18 When reading AC voltage signals, a true RMS meter (such as a Fluke 87) provides a different reading than an average responding meter (such as a Fluke 88). The only place this difference is important is when a reading is to be compared with a specification.
RMS VERSUS AVERAGE Alternating current voltage waveforms can be true sinusoidal or nonsinusoidal. A true sine wave pattern measurement will be the same for both root-mean-square (RMS) and average reading meters. RMS and averaging are two
methods used to measure the true effective rating of a signal that is constantly changing. SEE FIGURE 42–18. Only true RMS meters are accurate when measuring nonsinusoidal AC waveforms, which are seldom used in automotive applications.
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A 4 1/2-digit meter can display up to 19,000 counts of resolution. It is more precise to describe a meter by counts of resolution than by 3 1/2 or 4 1/2 digits. Some 3 1/2-digit meters have enhanced resolution of up to 3,200 or 4,000 counts.
Meters with more counts offer better resolution for certain measurements. For example, a 1,999 count meter will not be able to measure down to a tenth of a volt when measuring 200 volts or more. SEE FIGURE 42–19. However, a 3,200 count meter will display a tenth of a volt up to 320 volts. Digits displayed to the far right of the display may at times flicker or constantly change. This is called digit rattle and represents a changing voltage being measured on the ground (COM terminal of the meter lead). High-quality meters are designed to reject this unwanted voltage.
SAFETY TIP Meter Usage on Hybrid Electric Vehicles FIGURE 42–19 This meter display shows 052.2 AC volts. Notice that the zero beside the 5 indicates that the meter can read over 100 volts AC with a resolution of 0.1 volt. TECH TIP Purchase a Digital Meter That Will Work for Automotive Use Try to purchase a digital meter that is capable of reading the following: • • • • •
DC volts AC volts DC amperes (up to 10 A or more is helpful) Ohms (Ω) up to 40 MΩ (40 million ohms) Diode check
Additional features for advanced automotive diagnosis include: • • • •
Frequency (hertz, abbreviated Hz) Temperature probe (°F and/or °C) Pulse width (millisecond, abbreviated ms) Duty cycle (%)
RESOLUTION, DIGITS, AND COUNTS Meter resolution refers to how small or fine a measurement the meter can make. By knowing the resolution of a DMM you can determine whether the meter could measure down to only 1 volt or down to 1 millivolt (1/1,000 of a volt). You would not buy a ruler marked in 1 in. segments (or centimeters) if you had to measure down to 1/4 in. (or 1 mm). A thermometer that only measured in whole degrees is not of much use when your normal temperature is 98.6°F. You need a thermometer with 0.1° resolution. The terms digits and counts are used to describe a meter’s resolution. DMMs are grouped by the number of counts or digits they display.
A 3 1/2-digit meter can display three full digits ranging from 0 to 9, and one “half” digit that displays only a 1 or is left blank. A 3 1/2-digit meter will display up to 1,999 counts of resolution.
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CHAPTER 4 2
Many hybrid electric vehicles use system voltage as high as 650 volts DC. Be sure to follow all vehicle manufacturer’s testing procedures; and if a voltage measurement is needed, be sure to use a meter and test leads that are designed to insulate against high voltages. The International Electrotechnical Commission (IEC) has several categories of voltage standards for meter and meter leads. These categories are ratings for overvoltage protection and are rated CAT I, CAT II, CAT III, and CAT IV. The higher the category, the greater the protection against voltage spikes caused by high-energy circuits. Under each category there are various energy and voltage ratings. CAT I
Typically a CAT I meter is used for lowenergy voltage measurements such as at wall outlets in the home. Meters with a CAT I rating are usually rated at 300 to 800 volts.
CAT II
This higher rated meter would be typically used for checking higher energy level voltages at the fuse panel in the home. Meters with a CAT II rating are usually rated at 300 to 600 volts.
CAT III
This minimum rated meter should be used for hybrid vehicles. The CAT III category is designed for high-energy levels and voltage measurements at the service pole at the transformer. Meters with this rating are usually rated at 600 to 1,000 volts.
CAT IV
CAT IV meters are for clamp-on meters only. If a clamp-on meter also has meter leads for voltage measurements, that part of the meter will be rated as CAT III.
NOTE: Always use the highest CAT rating meter, especially when working with hybrid vehicles. A CAT III, 600 volt meter is safer than a CAT II, 1,000 volt meter because of the energy level of the CAT ratings. Therefore, for best personal protection, use only meters and meter leads that are CAT III or CAT IV rated when measuring voltage on a hybrid vehicle. SEE FIGURES 42–20 AND 42–21.
FIGURE 42–21 Always use meter leads that are CAT III rated on a meter that is also CAT III rated, to maintain the protection needed when working on hybrid vehicles. FIGURE 42–20 Be sure to only use a meter that is CAT III rated when taking electrical voltage measurements on a hybrid vehicle.
ACCURACY Meter accuracy is the largest allowable error that will occur under specific operating conditions. In other words, it is an indication of how close the DMM’s displayed measurement is to the actual value of the signal being measured. Accuracy for a DMM is usually expressed as a percent of reading. An accuracy of ±1% of reading means that for a displayed reading of 100.0 V, the actual value of the voltage could be anywhere between 99.0 V and 101.0 V. Thus, the lower the percent of accuracy is, the better.
Unacceptable ⫽ 1.00%
Okay ⫽ 0.50% (1/2%)
Good ⫽ 0.25% (1/4%)
Excellent ⫽ 0.10% (1/10%)
For example, if a battery had 12.6 volts, a meter could read between the following, based on its accuracy. ⫾0.1%
high ⫽ 12.61
low ⫽ 12.59
⫾0.25%
high ⫽ 12.63
low ⫽ 12.57
⫾0.50%
high ⫽ 12.66
low ⫽ 12.54
⫾1.00%
high ⫽ 12.73
low ⫽ 12.47
Before you purchase a meter, check the accuracy. Accuracy is usually indicated on the specifications sheet for the meter.
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DIGITAL METER USAGE
1
For most electrical measurements, the black meter lead is inserted in the terminal labeled COM and the red meter lead is inserted into the terminal labeled V.
2
To use a digital meter, turn the power switch and select the unit of electricity to be measured. In this case, the – rotary switch is turned to select DC volts. (V )
3
For most automotive electrical use, such as measuring battery voltage, select DC volts.
4
Connect the red meter lead to the positive (⫹) terminal of a battery and the black meter lead to the negative (⫺) terminal of a battery. The meter reads the voltage difference between the leads.
5
This jump start battery unit measures 13.151 volts with the meter set on autoranging on the DC voltage scale.
6
Another meter (Fluke 87 III) displays four digits when measuring the voltage of the battery jump start unit.
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CHAPTER 4 2
STEP BY STEP
7
To measure resistance turn the rotary dial to the ohm (Ω) symbol. With the meter leads separated, the meter display reads OL (over limit).
8
9
When measuring anything; be sure to read the symbol on the meter face. In this case, the meter is reading 291.10 kΩ.
10
A meter set on ohms can be used to check the resistance of a light bulb filament. In this case, the meter reads 3.15 ohms. If the bulb were bad (filament open), the meter would display OL.
12
The large letter V means volts and the wavy symbol over the V means that the meter measures alternating current (AC) voltage if this position is selected.
11
A digital meter set to read ohms should measure 0.00 as shown when the meter leads are touched together.
The meter can read your own body resistance if you grasp the meter lead terminals with your fingers. The reading on the display indicates 196.35 kΩ.
CONTINUED
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DIGITAL METER USAGE
(CONTINUED)
13
The next symbol is a V with a dotted and a straight line overhead. This symbol stands for direct current (DC) volts. This position is most used for automotive service.
14
The symbol mV indicates millivolts or 1/1000 of a volt (0.001). The solid and dashed line above the mV means DC mV.
15
The rotary switch is turned to Ω (ohms) unit of resistance measure. The symbol to the left of the Ω symbol is the beeper or continuity indicator.
16
Notice that AUTO is in the upper left and the MΩ is in the lower right. This MΩ means megaohms or that the meter is set to read in millions of ohms.
17
The symbol shown is the symbol of a diode. In this position, the meter applies a voltage to a diode and the meter reads the voltage drop across the junction of a diode.
18
One of the most useful features of this meter is the MIN/MAX feature. By pushing the MIN/MAX button, the meter will be able to display the highest (MAX) and the lowest (MIN) reading.
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CHAPTER 4 2
STEP BY STEP
19
Pushing the MIN/MAX button puts the meter into record mode. Note the 100 mS and “REC” on the display. In this position, the meter is capturing any voltage charge that lasts 100 mS (0.1 sec) or longer.
20
To increase the range of the meter touch the range button. Now the meter is set to read voltage up to 40 volts DC.
21
Pushing the range button one more time changes the meter scale to the 400-voltage range. Notice that the decimal point has moved to the right.
22
Pushing the range button again changes the meter to the 4000-volt range. This range is not suitable to use in automotive applications.
23
By pushing and holding the range button, the meter will reset to autorange. Autorange is the preferred setting for most automotive measurements except when using MIN/MAX record mode.
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REVIEW QUESTIONS 1. Why should high-impedance meters be used when measuring voltage on computer-controlled circuits?
3. Why must an ohmmeter be connected to a disconnected circuit or component?
2. How is an ammeter connected to an electrical circuit?
CHAPTER QUIZ 1. Inductive ammeters work because of what principle? a. Magic b. Electrostatic electricity c. A magnetic field surrounds any wire carrying a current d. Voltage drop as it flows through a conductor
6. A meter is set to read DC volts on the 4 volt scale. The meter leads are connected at a 12 volt battery. The display will read ______________. a. 0.00 c. 12 V b. OL d. 0.012 V
2. A meter used to measure amperes is called a(n) ______________. a. Amp meter c. Ammeter b. Ampmeter d. Coulomb meter
7. What could happen if the meter leads were connected to the positive and negative terminals of the battery while the meter and leads were set to read amperes? a. Could blow an internal fuse or damage the meter b. Would read volts instead of amperes c. Would display OL d. Would display 0.00
3. A voltmeter should be connected to the circuit being tested ______________. a. In series b. In parallel c. Only when no power is flowing d. Both a and c 4. An ohmmeter should be connected to the circuit or component being tested ______________. a. With current flowing in the circuit or through the component b. When connected to the battery of the vehicle to power the meter c. Only when no power is flowing (electrically open circuit) d. Both b and c 5. A high-impedance meter ______________. a. Measures a high amount of current flow b. Measures a high amount of resistance c. Can measure a high voltage d. Has a high internal resistance
chapter
43
8. The highest amount of resistance that can be read by the meter set to the 2 kΩ scale is ______________. a. 2,000 ohms b. 200 ohms c. 200 kΩ (200,000 ohms) d. 20,000,000 ohms 9. If a digital meter face shows 0.93 when set to read kΩ, the reading means ______________. a. 93 ohms c. 9,300 ohms b. 930 ohms d. 93,000 ohms 10. A reading of 432 shows on the face of the meter set to the millivolt scale. The reading means ______________. a. 0.432 volt c. 43.2 volts b. 4.32 volts d. 4,320 volts
OSCILLOSCOPES AND GRAPHING MULTIMETERS
OBJECTIVES: After studying Chapter 43, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic System Diagnosis). • Use a digital storage oscilloscope to measure voltage signals. • Interpret meter and scope readings and determine if the values are within factory specifications. • Explain time base and volts per division settings. KEY TERMS: AC coupling 462 • BNC connector 465 • Cathode ray tube (CRT) 461 • Channel 464 • DC coupling 462 • Digital storage oscilloscope (DSO) 461 • Division 462 • Duty cycle 464 • External trigger 464 • Frequency 463 • GMM 466 • Graticule 461 • Hertz 463 • Oscilloscope (scope) 461 • Pulse train 463 • Pulse width 464 • PWM 464 • Time base 462 • Trigger level 464 • Trigger slope 464
460
CHAPTER 4 3
1 VOLT
8 VOLTS VOLTS/DIV SET 1 VOLT 500 ms OR (0.50 s) OR 1/2 OF 1 SECOND TIME BASE SET TO "50 ms"
FIGURE 43–1 A scope display allows technicians to take measurements of voltage patterns. In this example, each vertical division is 1 volt and each horizontal division is set to represent 50 milliseconds.
is preferred. Sampling rate means that a scope is capable of capturing voltage changes that occur over a very short period of time. Some digital storage scopes have a capture rate of 25 million (25,000,000) samples per second. This means that the scope can capture a glitch (fault) that lasts just 40 nano (0.00000040) seconds long.
TYPES OF OSCILLOSCOPES TERMINOLOGY
An oscilloscope (usually called a scope) is a visual voltmeter with a timer that shows when a voltage changes. Following are several types of oscilloscopes.
An analog scope uses a cathode ray tube (CRT) similar to a television screen to display voltage patterns. The scope screen displays the electrical signal constantly. A digital scope commonly uses a liquid crystal display (LCD), but a CRT may also be used on some digital scopes. A digital scope takes samples of the signals that can be stopped or stored and is therefore called a digital storage oscilloscope, or DSO.
A digital scope does not capture each change in voltage but instead captures voltage levels over time and stores them as dots. Each dot is a voltage level. Then the scope displays the waveforms using the thousands of dots (each representing a voltage level) and then electrically connects the dots to create a waveform.
A DSO can be connected to a sensor output signal wire and can record over a long period of time the voltage signals. Then it can be replayed and a technician can see if any faults were detected. This feature makes a DSO the perfect tool to help diagnose intermittent problems.
A digital storage scope, however, can sometimes miss faults called glitches that may occur between samples captured by the scope. This is why a DSO with a high “sampling rate”
A scope has been called “a voltmeter with a clock.”
The voltmeter part means that a scope can capture and display changing voltage levels.
The clock part means that the scope can display these changes in voltage levels within a specific time period; and with a DSO it can be replayed so that any faults can be seen and studied.
OSCILLOSCOPE DISPLAY GRID A typical scope face usually has eight or ten grids vertically (up and down) and ten grids horizontally (left to right). The transparent scale (grid), used for reference measurements, is called a graticule. This arrangement is commonly 8 ⫻ 10 or 10 ⫻ 10 divisions. SEE FIGURE 43–1. NOTE: These numbers originally referred to the metric dimensions of the graticule in centimeters. Therefore, an 8 ⴛ 10 display would be 8 cm (80 mm or 3.14 in.) high and 10 cm (100 mm or 3.90 in.) wide.
Voltage is displayed on a scope starting with zero volts at the bottom and higher voltage being displayed vertically.
The scope illustrates time left to right. The pattern starts on the left and sweeps across the screen from left to right.
O SC I L L O SC O PE S AN D G RAPH I N G M U L T IM ET ERS
461
MILLISECONDS PER DIVISION (MS/DIV)
4.72 V 680 MV
TOTAL TIME DISPLAYED
1 ms
10 ms (0.010 sec.)
10 ms
100 ms (0.100 sec.)
50 ms
MAXIMUM
HOLD
MINIMUM
5V 4 3 2
500 ms (0.500 sec.)
1
100 ms
1 sec. (1.000 sec.)
500 ms
5 sec. (5.0 sec.)
0 -1V 100MS / DIV
1,000 ms CHART 43–1
The time base is milliseconds (ms) and total time of an event that can be displayed.
SCOPE SETUP AND ADJUSTMENTS SETTING THE TIME BASE Most scopes use 10 graticules from left to right on the display. Setting the time base means setting how much time will be displayed in each block called a division. For example, if the scope is set to read 2 seconds per division (referred to as s/div), then the total displayed would be 20 seconds (2 ⫻ 10 divisions ⫽ 20 sec.). The time base should be set to an amount of time that allows two to four events to be displayed. Milliseconds (0.001 sec.) are commonly used in scopes when adjusting the time base. Sample time is milliseconds per division (indicated as ms/div) and total time. SEE CHART 43–1. NOTE: Increasing the time base reduces the number of samples per second. The horizontal scale is divided into 10 divisions (sometimes called grats). If each division represents 1 second of time, then the total time period displayed on the screen will be 10 seconds. The time per division is selected so that several events of the waveform are displayed. Time per division settings can vary greatly in automotive use, including:
MAP/MAF sensors: 2 ms/div (20 ms total)
Network (CAN) communications network: 2 ms/div (20 ms total)
Throttle position (TP) sensor: 100 ms per division (1 sec. total)
Fuel injector: 2 ms/div (20 ms total)
Oxygen sensor: 1 sec. per division (10 sec. total)
Primary ignition: 10 ms/div (100 ms total)
Secondary ignition: 10 ms/div (100 ms total)
Voltage measurements: 5 ms/div (50 ms total)
The total time displayed on the screen allows comparisons to see if the waveform is consistent or is changing. Multiple waveforms shown on the display at the same time also allow for measurements to be seen more easily. SEE FIGURE 43–2 for an example of a throttle position sensor waveform created by measuring the voltage output as the throttle was depressed and then released.
VOLTS PER DIVISION
The volts per division, abbreviated V/div, should be set so that the entire anticipated waveform can be viewed. Examples include: Throttle position (TP) sensor: 1 V/div (8 V total) Battery, starting and charging: 2 V/div (16 V total) Oxygen sensor: 200 mV/div (1.6 V total)
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CHAPTER 4 3
KEYS
10 sec. (10.0 sec.)
POTENTIOMETER SWEEP TEST
RANGE
FIGURE 43–2 The display on a digital storage oscilloscope (DSO) displays the entire waveform of a throttle position (TP) sensor from idle to wide-open throttle and then returns to idle. The display also indicates the maximum reading (4.72 V) and the minimum (680 mV or 0.68 V). The display does not show anything until the throttle is opened, because the scope has been set up to only start displaying a waveform after a certain voltage level has been reached. This voltage is called the trigger or trigger point.
Notice from the examples that the total voltage to be displayed exceeds the voltage range of the component being tested. This ensures that all the waveform will be displayed. It also allows for some unexpected voltage readings. For example, an oxygen sensor should read between 0 V and 1 V (1,000 mV). By setting the V/div to 200 mV, up to 1.6 V (1,600 mV) will be displayed.
DC AND AC COUPLING DC COUPLING
DC coupling is the most used position on a scope because it allows the scope to display both alternating current (AC) voltage signals and direct current (DC) voltage signals present in the circuit. The AC part of the signal will ride on top of the DC component. For example, if the engine is running and the charging voltage is 14.4 volts DC, this will be displayed as a horizontal line on the screen. Any AC ripple voltage leaking past the alternator diodes will be displayed as an AC signal on top of the horizontal DC voltage line. Therefore, both components of the signal can be observed at the same time.
AC COUPLING When the AC coupling position is selected, a capacitor is placed into the meter lead circuit, which effectively blocks all DC voltage signals but allows the AC portion of the signal to pass and be displayed. AC coupling can be used to show output signal waveforms from sensors such as:
Distributor pickup coils
Magnetic wheel speed sensors
Magnetic crankshaft position sensors
Magnetic camshaft position sensors
Magnetic vehicle speed sensors
The AC ripple from an alternator. SEE FIGURE 43–3.
NOTE: Check the instructions from the scope manufacturer for the recommended settings to use. Sometimes it is necessary to switch from DC coupling to AC coupling or from AC coupling to DC coupling to properly see some waveforms.
PULSE TRAINS DEFINITION
Scopes can show all voltage signals. Among the most commonly found in automotive applications is a DC voltage that varies up and down and does not go below zero like an AC voltage. A DC voltage that turns on and off in a series of pulses is called a pulse train. Pulse trains differ from an AC signal in that they do not go below zero. An alternating voltage goes above and below zero voltage. Pulse train signals can vary in several ways. SEE FIGURE 43–4.
FREQUENCY FIGURE 43–3 Ripple voltage is created from the AC voltage from an alternator. Some AC ripple voltage is normal but if the AC portion exceeds 0.5 volt, then a bad diode is the most likely cause. Excessive AC ripple can cause many electrical and electronic devices to work incorrectly.
Frequency is the number of cycles per second measured in hertz. The engine revolutions per minute (RPM) signal is an example of a signal that can occur at various frequencies. At low engine speed, the ignition pulses occur fewer times per second (lower frequency) than when the engine is operated at higher engine speeds (RPM).
1. FREQUENCY - FREQUENCY IS THE NUMBER OF CYCLES THAT TAKE PLACE PER SECOND. THE MORE CYCLES THAT TAKE PLACE IN ONE SECOND, THE HIGHER THE FREQUENCY READING. FREQUENCIES ARE MEASURED IN HERTZ, WHICH IS THE NUMBER OF CYCLES PER SECOND. AN EIGHT HERTZ SIGNAL CYCLES EIGHT TIMES PER SECOND. I SECOND
THIS IS WHAT AN 8 HERTZ WOULD LOOK LIKE - 8 HERTZ MEANS "8 CYCLES PER SECOND."
2. DUTY CYCLE - DUTY CYCLE IS A MEASUREMENT COMPARING THE SIGNAL ON-TIME TO THE LENGTH OF ONE COMPLETE CYCLE. AS ON-TIME INCREASES, OFF-TIME DECREASES. DUTY CYCLE IS MEASURED IN PERCENTAGE OF ON-TIME. A 60% DUTY CYCLE IS A SIGNAL THAT'S ON 60% OF THE TIME, AND OFF 40% OF THE TIME. ANOTHER WAY TO MEASURE DUTY CYCLE IS DWELL, WHICH IS MEASURED IN DEGREES INSTEAD OF PERCENT. 1 CYCLE ON-TIME OFF ON DUTY CYCLE IS THE RELATIONSHIP BETWEEN ONE COMPLETE CYCLE, AND THE SIGNAL'S ON-TIME. A SIGNAL CAN VARY IN DUTY CYCLE WITHOUT AFFECTING THE FREQUENCY.
3. PULSE WIDTH - PULSE WIDTH IS THE ACTUAL ON-TIME OF A SIGNAL, MEASURED IN MILLISECONDS. WITH PULSE WIDTH MEASUREMENTS, OFF-TIME DOESN'T REALLY MATTER - THE ONLY REAL CONCERN IS HOW LONG THE SIGNAL'S ON. THIS IS A USEFUL TEST FOR MEASURING CONVENTIONAL INJECTOR ON-TIME, TO SEE THAT THE SIGNAL VARIES WITH LOAD CHANGE. PULSE WIDTH
OFF ON PULSE WIDTH IS THE ACTUAL TIME A SIGNAL'S ON, MEASURED IN MILLISECONDS. THE ONLY THING BEING MEASURED IS HOW LONG THE SIGNAL IS ON.
FIGURE 43–4 A pulse train is any electrical signal that turns on and off, or goes high and low in a series of pulses. Ignition module and fuel-injector pulses are examples of a pulse train signal.
O SC I L L O SC O PE S AN D G RAPH I N G M U L T IM ET ERS
463
ON-TIME
GROUND CONTROLLED ON-TIME
OFF
ON
I COMPLETE CYCLE ON A GROUND-CONTROLLED CIRCUIT, THE ON-TIME PULSE IS THE LOWER HORIZONTAL PULSE.
I COMPLETE CYCLE
(a)
FEED CONTROLLED ON-TIME
ON
DIGITAL MULTIMETER AUTO
TRIG
082.4
% 40
OFF
THE % SIGN IN THE UPPER RIGHT CORNER OF THE DISPLAY INDICATES THAT THE METER IS READING A DUTY CYCLE SIGNAL. (b)
FIGURE 43–5 (a) A scope representation of a complete cycle showing both on-time and off-time. (b) A meter display indicating the on-time duty cycle in a percentage (%). Note the trigger and negative (⫺) symbol. This indicates that the meter started to record the percentage of on-time when the voltage dropped (start of on-time).
I COMPLETE CYCLE ON A FEED-CONTROLLED CIRCUIT, THE ON-TIME PULSE IS THE UPPER HORIZONTAL PULSE.
FIGURE 43–6 Most automotive computer systems control the device by opening and closing the ground to the component.
Four channel. A four-channel scope allows the technician to view up to four different sensors or actuators on one display.
NOTE: Often the capture speed of the signals is slowed when using more than one channel.
DUTY CYCLE
Duty cycle refers to the percentage of on-time of the signal during one complete cycle. As on-time increases, the amount of time the signal is off decreases and is usually measured in percentage. Duty cycle is also called pulse-width modulation (PWM) and can be measured in degrees. SEE FIGURE 43–5.
PULSE WIDTH The pulse width is a measure of the actual ontime measured in milliseconds. Fuel injectors are usually controlled by varying the pulse width. SEE FIGURE 43–6.
TRIGGERS EXTERNAL TRIGGER
An external trigger is when the waveform starts when a signal is received from another external source rather than from the signal pickup lead. A common example of an external trigger comes from the probe clamp around the cylinder #1 spark plug wire to trigger the start of an ignition pattern.
TRIGGER LEVEL
NUMBER OF CHANNELS DEFINITION
Scopes are available that allow the viewing of more than one sensor or event at the same time on the display. The number of events, which require leads for each, is called a channel. A channel is an input to a scope. Commonly available scopes include:
Single channel. A single channel scope is capable of displaying only one sensor signal waveform at a time.
Two channel. A two-channel scope can display the waveform from two separate sensors or components at the same time. This feature is very helpful when testing the camshaft and crankshaft position sensors on an engine to see if they are properly timed. SEE FIGURE 43–7.
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Trigger level is the voltage that must be detected by the scope before the pattern will be displayed. A scope will only start displaying a voltage signal when it is triggered or is told to start. The trigger level must be set to start the display. If the pattern starts at 1 volt, then the trace will begin displaying on the left side of the screen after the trace has reached 1 volt.
TRIGGER SLOPE
The trigger slope is the voltage direction that a waveform must have in order to start the display. Most often, the trigger to start a waveform display is taken from the signal itself. Besides trigger voltage level, most scopes can be adjusted to trigger only when the voltage rises past the trigger-level voltage. This is called a positive slope. When the voltage falling past the higher level activates the trigger, this is called a negative slope. The scope display indicates both a positive and a negative slope symbol. For example, if a waveform such as a magnetic sensor used for crankshaft position or wheel speed starts moving upward, a
CHANNEL 1
CHANNEL 2
10mSec/Div 5Volts/Div
FIGURE 43–7 A two-channel scope being used to compare two signals on the same vehicle.
(a)
(b)
FIGURE 43–8 (a) A symbol for a positive trigger—a trigger occurs at a rising (positive) edge of the signal (waveform). (b) A symbol for a negative trigger—a trigger occurs at a falling (negative) edge of the signal (waveform). positive slope should be selected. If a negative slope is selected, the waveform will not start showing until the voltage reaches the trigger level in a downward direction. A negative slope should be used when a fuel-injector circuit is being analyzed. In this circuit, the computer provides the ground and the voltage level drops when the computer commands the injector on. Sometimes the technician needs to change from negative to positive or positive to negative trigger if a waveform is not being shown correctly. SEE FIGURE 43–8.
AUTOMOTIVE SCOPMETER HOLD
12.8 V 10.1 V 13.8 V
START OF SIGNAL
HOLD
MINIMUM
25 20 15 10
END OF SIGNAL
5 0 -5 VEHICLE DATA
PRADE SINGLE
RANGE
14V 12
MENU
RECORD
10 SAVE RECALL
AUTO RANGE
8 6
USING A SCOPE USING SCOPE LEADS
Most scopes, both analog and digital, normally use the same test leads. These leads usually attach to the scope through a BNC connector, a miniature standard coaxial cable connector. BNC is an international standard that is used in the electronics industry. If using a BNC connector, be sure to connect one lead to a good clean, metal engine ground. The probe of the scope lead attaches to the circuit or component being tested. Many scopes use one ground lead and then each channel has it own signal pickup lead.
MEASURING BATTERY VOLTAGE WITH A SCOPE One of the easiest things to measure and observe on a scope is battery voltage. A lower voltage can be observed on the scope display as the engine is started and a higher voltage should be displayed after the engine starts. SEE FIGURE 43–9.
200MS/DIV
BATTERY TEST
KEYS RANGE
FIGURE 43–9 Constant battery voltage is represented by a flat horizontal line. In this example, the engine was started and the battery voltage dropped to about 10 V as shown on the left side of the scope display. When the engine started, the alternator started to charge the battery and the voltage is shown as climbing.
An analog scope displays rapidly and cannot be set to show or freeze a display. Therefore, even though an analog scope shows all voltage signals, it is easy to miss a momentary glitch on an analog scope. CAUTION: Check the instructions for the scope being used before attempting to scope household AC circuits. Some scopes, such as the Snap-On MODIS, are not designed to measure high-voltage AC circuits.
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GRAPHING MULTIMETER A graphing multimeter, abbreviated GMM, is a cross between a digital meter and a digital storage oscilloscope. A graphing multimeter displays the voltage levels at two places:
On a display screen
In a digital readout
It is usually not capable of capturing very short duration faults or glitches that would likely be captured with a digital storage oscilloscope. SEE FIGURE 43–10.
GRAPHING SCAN TOOLS
FIGURE 43–10 A typical graphing multimeter that can be used as a digital meter, plus it can display the voltage levels on the display screen.
Many scan tools are capable of displaying the voltage levels captured by the scan tool through the data link connector (DLC) on a screen. This feature is helpful where seeing changes in voltage levels is difficult to detect by looking at numbers that are constantly changing. Read and follow the instructions for the scan tool being used.
REVIEW QUESTIONS 1. What are the differences between an analog and a digital oscilloscope? 2. What is the difference between DC coupling and AC coupling?
3. Why are DC signals that change called pulse trains? 4. What is the difference between an oscilloscope and a graphing multimeter?
CHAPTER QUIZ 1. Technician A says an analog scope can store the waveform for viewing later. Technician B says that the trigger level has to be set on most scopes to be able to view a changing waveform. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 2. An oscilloscope display is called a ______________. a. Grid c. Division b. Graticule d. Box 3. A signal showing the voltage of a battery displayed on a digital storage oscilloscope (DSO) is being discussed. Technician A says that the display will show one horizontal line above the zero line. Technician B says that the display will show a line sloping upward from zero to the battery voltage level. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 4. Setting the time base to 50 ms per division will allow the technician to view a waveform how long in duration? a. 50 ms c. 400 ms b. 200 ms d. 500 ms 5. A throttle position sensor waveform is going to be observed. At what setting should the volts per division be set to see the entire waveform from 0 to 5 volts? a. 0.5 V/division c. 2.0 V/division b. 1.0 V/division d. 5.0 V/division
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6. Two technicians are discussing the DC coupling setting on a DSO. Technician A says that the position allows both the DC and AC signals of the waveform to be displayed. Technician B says that this setting allows just the DC part of the waveform to be displayed. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 7. Voltage signals (waveforms) that do not go below zero are called ______________. a. AC signals b. Pulse trains c. Pulse width d. DC coupled signals 8. Cycles per second are expressed in ______________. a. Hertz c. Pulse width b. Duty cycle d. Slope 9. Oscilloscopes use what type of lead connector? a. Banana plugs c. Single conductor plugs b. Double banana plugs d. BNC 10. A digital meter that can show waveforms is called a ______________. a. DVOM c. GMM b. DMM d. DSO
chapter
44
AUTOMOTIVE WIRING AND WIRE REPAIR
OBJECTIVES: After studying Chapter 44, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic Systems Diagnosis). • Explain the wire gauge number system. • Describe how fusible links and fuses protect circuits and wiring. • Discuss electrical terminals and connectors • Describe how to solder • Discuss circuit breakers and PTC electronic circuit protection devices. • Explain the types of electrical conduit. • List the steps for performing a proper wire repair. KEY TERMS: Adhesive-lined heat shrink tubing 476 • American wire gauge (AWG) 467 • Auto link 471 • Battery cables 469 • Braided ground straps 468 • Circuit breakers 472 • Cold solder joint 476 • Connector 474 • CPA 474 • Crimp-and-seal connectors 476 • Fuse link 471 • Fuses 469 • Fusible link 473 • Heat shrink tubing 476 • Jumper cables 469 • Lock tang 474 • Metric wire gauge 467 • Pacific fuse element 471 • Primary wire 468 • PTC circuit protectors 472 • Rosin-core solder 475 • Skin effect 468 • Terminal 474 • Twisted pair 469
AUTOMOTIVE WIRING DEFINITION AND TERMINOLOGY
Most automotive wire is made from strands of copper covered by plastic insulation. Copper is an excellent conductor of electricity that is reasonably priced and very flexible. However, solid copper wire can break when moved repeatedly; therefore, most copper wiring is constructed of multiple small strands that allow for repeated bending and moving without breaking. Solid copper wire is generally used for components such as starter armature and alternator stator windings that do not bend or move during normal operation. Copper is the best electrical conductor besides silver, which is a great deal more expensive. The conductivity of various metals is rated. SEE CHART 44–1.
AMERICAN WIRE GAUGE
Wiring is sized and purchased according to gauge size as assigned by the American wire gauge (AWG) system. AWG numbers can be confusing because as the gauge number increases, the size of the conductor wire decreases. Therefore, a 14 gauge wire is smaller than a 10 gauge wire. The greater the amount of current (in amperes) that is flowing through a wire, the larger the diameter (smaller gauge number) that will be required. SEE CHART 44–2, which compares the AWG number to the actual wire diameter in inches. The diameter refers to the diameter of the metal conductor and does not include the insulation. Following are general applications for the most commonly used wire gauge sizes. Always check the installation instructions or the manufacturer’s specifications for wire gauge size before replacing any automotive wiring.
20 to 22 gauge: radio speaker wires
18 gauge: small bulbs and short leads
16 gauge: taillights, gas gauge, turn signals, windshield wipers
14 gauge: horn, radio power lead, headlights, cigarette lighter, brake lights
1.
Silver
2.
Copper
3.
Gold
4.
Aluminum
5.
Tungsten
6.
Zinc
7.
Brass (copper and zinc)
8.
Platinum
9.
Iron
10.
Nickel
11.
Tin
12.
Steel
13.
Lead
CHART 44–1 The list of relative conductivity of metals, showing silver to be the best.
12 gauge: headlight switch-to-fuse box, rear window defogger, power windows and locks
10 gauge: alternator-to-battery
4, 2, or 0 (1/0) gauge: battery cables
METRIC WIRE GAUGE Most manufacturers indicate on the wiring diagrams the metric wire gauge sizes measured in square millimeters (mm2) of cross-sectional area. The following chart gives conversions or comparisons between metric gauge and AWG sizes. Notice that the metric wire size increases with size (area), whereas the AWG size gets smaller with larger size wire. SEE CHART 44–3. The AWG number should be decreased (wire size increased) with increased lengths of wire. SEE CHART 44–4.
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WIRE GAUGE DIAMETER TABLE AMERICAN WIRE GAUGE (AWG)
WIRE DIAMETER IN INCHES
RECOMMENDED WIRE GAUGE (AWG) (FOR LENGTH IN FEET)*
12 V AMPS
3⬘
5⬘
7⬘
10⬘
15⬘
20⬘
25⬘
5
18
18
18
18
18
18
18
0.0508214
7
18
18
18
18
18
18
16
0.064084
10
18
18
18
18
16
16
16
0.08080810
12
18
18
18
18
16
16
14
10
0.10189
15
18
18
18
18
14
14
12
8
0.128496
18
18
18
16
16
14
14
12
6
0.16202
20
18
18
16
16
14
12
10
5
0.18194
22
18
18
16
16
12
12
10
4
0.20431
24
18
18
16
16
12
12
10
3
0.22942
30
18
16
16
14
10
10
10
2
0.25763
40
18
16
14
12
10
10
8
1
0.2893
50
16
14
12
12
10
10
8
0
0.32486
100
12
12
10
10
6
6
4
00
0.3648
150
10
10
8
8
4
4
2
200
10
8
8
6
4
4
2
20
0.03196118
18
0.040303
16 14 12
CHART 44–2 American wire gauge (AWG) number and the actual conductor diameter in inches.
METRIC SIZE (MM2)
AWG SIZE
0.5
20
0.8
18
1.0
16
2.0
14
3.0
12
5.0
10
8.0
8
13.0
6
19.0
4
32.0
2
52.0
0
CHART 44–4 Recommended AWG wire size increases as the length increases because all wire has internal resistance. The longer the wire is, the greater the resistance. The larger the diameter is, the lower the resistance. *When mechanical strength is a factor, use the next larger wire gauge.
For example, a trailer may require 14 gauge wire to light all the trailer lights, but if the wire required is over 25 ft long, 12 gauge wire should be used. Most automotive wire, except for spark plug wire, is often called primary wire (named for the voltage range used in the primary ignition circuit) because it is designed to operate at or near battery voltage.
GROUND WIRES
CHART 44–3 Metric wire size in squared millimeters (mm2) conversion chart to American wire gauge (AWG).
?
FREQUENTLY ASKED QUESTION
Do They Make 13 Gauge Wire? Yes. AWG sizing of wire includes all gauge numbers, including 13, even though the most commonly used sizes are even numbered, such as 12, 14, or 16. Because the sizes are so close, wire in every size is not commonly stocked, but can be ordered for a higher price. Therefore, if a larger wire size is needed, it is common practice to select the next lower, even-numbered gauge.
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PURPOSE AND FUNCTION
All vehicles use ground wires between the engine and body and/or between the body and the negative terminal of the battery. The two types of ground wires are:
Insulated copper wire
Braided ground straps
Braided grounds straps are uninsulated. It is not necessary to insulate a ground strap because it does not matter if it touches metal, as it already attaches to ground. Braided ground straps are more flexible than stranded wire. Because the engine will move slightly on its mounts, the braided ground strap must be able to flex without breaking. SEE FIGURE 44–1.
SKIN EFFECT
The braided strap also dampens out some radiofrequency interference that otherwise might be transmitted through standard stranded wiring due to the skin effect. The skin effect is the term used to describe how high-frequency AC electricity flows through a conductor. Direct current flows through
BRAIDED GROUND STRAP USED TO GROUND THE HOOD TO REDUCE RADIO INTERFERENCE
BRAIDED GROUND STRAP CONNECTING THE BODY TO THE ENGINE
FIGURE 44–1 All lights and accessories ground to the body of the vehicle. Body ground wires such as this one are needed to conduct all of the current from these components back to the negative terminal of the battery. The body ground wire connects the body to the engine. Most battery negative cables attach to the engine.
?
FREQUENTLY ASKED QUESTION
What Is a Twisted Pair? A twisted pair is used to transmit low-voltage signals using two wires that are twisted together. Electromagnetic interference can create a voltage in a wire and twisting the two signal wires cancels out the induced voltage. A twisted pair means that the two wires have at least nine turns per foot (turns per meter). A rule of thumb is a twisted pair should have one twist per inch of length.
a conductor, but alternating current tends to travel through the outside (skin) of the conductor. Because of the skin effect, most audio (speaker) cable is constructed of many small-diameter copper wires instead of fewer larger strands, because the smaller wire has a greater surface area and therefore results in less resistance to the flow of AC voltage. NOTE: Body ground wires are necessary to provide a circuit path for the lights and accessories that ground to the body and flow to the negative battery terminal.
BATTERY CABLES Battery cables are the largest wires used in the automotive electrical system. The cables are usually 4 gauge, 2 gauge, or 1 gauge wires (19 mm2 or larger). SEE FIGURE 44–2. Wires larger than 1 gauge are called 0 gauge (pronounced “ought”). Larger cables are labeled 2/0 or 00 (2 ought) and 3/0 or 000 (3 ought). Electrical systems that are 6 volts require battery cables two sizes larger than those used for 12 volt electrical systems, because the lower voltage used in antique vehicles resulted in twice the amount of current (amperes) to supply the same electrical power.
FIGURE 44–2 Battery cables are designed to carry heavy starter current and are therefore usually 4 gauge or larger wire. Note that this battery has a thermal blanket covering to help protect the battery from high underhood temperatures. The wiring is also covered with plastic conduit called split-loom tubing.
JUMPER CABLES Jumper cables are 4 to 2/0 gauge electrical cables with large clamps attached and are used to connect a vehicle that has a discharged battery to a vehicle that has a good battery. Good-quality jumper cables are necessary to prevent excessive voltage drops caused by cable resistance. Aluminum wire jumper cables should not be used, because even though aluminum is a good electrical conductor (although not as good as copper), it is less flexible and can crack and break when bent or moved repeatedly. The size should be 6 gauge or larger. 1/0 AWG welding cable can be used to construct an excellent set of jumper cables using welding clamps on both ends. Welding cable is usually constructed of many very fine strands of wire, which allow for easier bending of the cable as the strands of fine wire slide against each other inside the cable. NOTE: Always check the wire gauge of any battery cables or jumper cables and do not rely on the outside diameter of the wire. Many lower cost jumper cables use smaller gauge wire, but may use thick insulation to make the cable look as if it is the correct size wire.
FUSES AND CIRCUIT PROTECTION DEVICES CONSTRUCTION Fuses should be used in every circuit to protect the wiring from overheating and damage caused by excessive current flow as a result of a short circuit or other malfunction. The symbol for a fuse is a wavy line between two points: A fuse is constructed of a fine tin conductor inside a glass, plastic, or ceramic housing. The tin is designed to melt and open the circuit if excessive current flows through the fuse. Each fuse is rated according to its maximum current-carrying capacity.
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FUSE (TEN) (5 AMP.) INSTRUMENT ILLUMINATING LAMPS, HEADLAMP ON WARNING AND ELECTRONIC A/C
HEADLAMP ON WARNING AND ELECTRONIC A/C FUSE (WHITE) (25 AMP.) WINDSHIELD, WIPER AND WASHER AND LOW WASHER FLUID
CIRCUIT BREAKER POWER WINDOWS, ROOF AND FUEL CAP LOCK RELEASE (30 AMP.)
FUSE (YELLOW) (20 AMP.)
FUSE (WHITE) (25 AMP.) HEATER, A/C, RADIO CAPACITOR AND DECK LID
FUSE (TEN) (10 AMP.)
RADIO CAPACITOR
HEADLAMP ON WARNING, MAPLIGHT, TRANS-DOWN SHIFT
FUSE (RED) (10 AMP.) ECM BATTERY FEED FUSE (YELLOW) (20 AMP.) STOP AND HAZARD LAMPS
FUSE (YELLOW) (20 AMP.) SEAT BELT LIGHT AND BUZZER, HEATED BACKLIGHT RELAY, MAP LIGHT AND TRANS-DOWN SHIFT
CIRCUIT BREAKER POWER SEAT, DOOR LOCKS, HEATED BACKLIGHT FEED AND TAILGATE WINDOW (30 AMP.) FUSE (YELLOW) (20 AMP.) CLOCK, CIGAR LIGHTER, GLOVE BOX LAMP, SPEED/KEY BUZZER, POWER ANTENNA, CLOCK RADIO, ELECTRONIC A/C
FUSE (YELLOW) (20 AMP.) TAIL, SIDE MAKER, PARK, CORNER, LICENCE LAMP AND CLOCK RADIO FUSE (RED) (10 AMP.) RADIO
FUSE (YELLOW) (20 AMP.) SOME, SAIL PANEL, TRUNK, READING, VANITY, HEADLAMP ON WARNING, AUTO-DOOR LOCKS, AND REAR CIGAR LIGHTER
FUSE (YELLOW) (20 AMP.) TURN SIGNALS AND BACK-UP LAMPS TEST POINT FOR TRANS-CLUTCH CONVERTERS
HEATED BACK LIGHT BODY WIRING JUNCTION BLOCK (POWER SEAT AND DOOR LOCKS) POWER ANTENNA, DIGITAL CLOCK RADIO, ELECTRONIC A/C NOT USED
FUSE (RED) (10 AMP.) INSTRUMENT GAGES, INDICATOR LIGHT, TRANSCONVERTER CLUTCH AND CRUISE CONTROL AND ECM
FIGURE 44–3 A typical automotive fuse panel.
NORMAL CURRENT IN THE CIRCUIT (AMPERES)
FUSE RATING
1
Dark green
7.5 A
10 A
2
Gray
16 A
20 A
2.5
Purple
24 A
30 A
3
Violet
4
Pink
5
Tan
6
Gold
7.5
Brown
9
Orange
AMPERAGE RATING
CHART 44–5 The fuse rating should be 20% higher than the maximum current in the circuit to provide the best protection for the wiring and the component being protected.
Many fuses are used to protect more than one circuit of the automobile. SEE FIGURE 44–3. A typical example is the fuse for the cigarette lighter that also protects many other circuits, such as those for the courtesy lights, clock, and other circuits. A fault in one of these circuits can cause this fuse to melt, which will prevent the operation of all other circuits that are protected by the fuse.
COLOR
10
Red
14
Black
15
Blue
20
Yellow
25
White
30
Green
CHART 44–6
NOTE: The SAE term for a cigarette lighter is cigar lighter because the diameter of the heating element is large enough for a cigar. The term cigarette lighter will be used throughout this book because it is the most common usage.
The amperage rating and the color of the blade fuse are standardized.
FUSE RATINGS Fuses are used to protect the wiring and components in the circuit from damage if an excessive amount of current flows. The fuse rating is normally about 20% higher than the normal current in the circuit. SEE CHART 44–5 for a typical fuse rating based on the normal current in the circuit. In other words, the normal current flow should be about 80% of the fuse rating.
BLADE FUSES Colored blade-type fuses are also referred to as ATO fuses and have been used since 1977. The color of the plastic of blade fuses indicates the maximum current flow, measured in amperes. SEE CHART 44–6 for the color and the amperage rating of blade fuses.
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FUSE TEST POINTS
20
FIGURE 44–4 Blade-type fuses can be tested through openings in the plastic at the top of the fuse.
AMPERAGE RATING 5
FIGURE 44–5 Three sizes of blade-type fuses: mini on the left, standard or ATO type in the center, and maxi on the right.
COLOR
TOP
Tan
7.5
Brown
10
Red
15
Blue
20
Yellow
25
Natural
30
Green
CHART 44–7 Mini fuse amperage rating and colors.
AMPERAGE RATING
COLOR
20
Yellow
30
Green
40
Amber
50
Red
60
Blue
70
Brown
80
Natural
SIDE
FUSE ELEMENT (PACIFIC FUSE)
MAXIFUSE
ATO FUSE
MINIFUSE
FIGURE 44–6 A comparison of the various types of protective devices used in most vehicles.
CHART 44–8 Maxi fuse amperage rating and colors.
SEE FIGURE 44–5 for a comparison of the various sizes of blade-type fuses.
Each fuse has an opening in the top of its plastic portion to allow access to its metal contacts for testing purposes. SEE FIGURE 44–4.
PACIFIC FUSE ELEMENT
MINI FUSES
To save space, many vehicles use mini (small) blade fuses. Not only do they save space but they also allow the vehicle design engineer to fuse individual circuits instead of grouping many different components on one fuse. This improves customer satisfaction because if one component fails, it only affects that one circuit without stopping electrical power to several other circuits as well. This makes troubleshooting a lot easier too, because each circuit is separate. SEE CHART 44–7 for the amperage rating and corresponding fuse color for mini fuses.
MAXI FUSES
Maxi fuses are a large version of blade fuses and are used to replace fusible links in many vehicles. Maxi fuses are rated up to 80 amperes or more. SEE CHART 44–8 for the amperage rating and corresponding color for maxi fuses.
First used in the late 1980s, Pacific fuse elements (also called a fuse link or auto link) are used to protect wiring from a direct short-to-ground. The housing contains a short link of wire sized for the rated current load. The transparent top allows inspection of the link inside. SEE FIGURE 44–6.
TESTING FUSES It is important to test the condition of a fuse if the circuit being protected by the fuse does not operate. Most blown fuses can be detected quickly because the center conductor is melted. Fuses can also fail and open the circuit because of a poor connection in the fuse itself or in the fuse holder. Therefore, just because a fuse “looks okay” does not mean that it is okay. All fuses should be tested with a test light. The test light should be connected to first one side of the fuse and then the other. A test light should light on both sides. If the test light only lights on one side, the fuse is blown or open. If the test light does not light on either side of the fuse, then that circuit is not being supplied power. SEE FIGURE 44–7. An ohmmeter can be used to test fuses.
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CIRCUIT BREAKER
FIGURE 44–9 Electrical symbols used to represent circuit breakers.
FIGURE 44–7 To test a fuse, use a test light to check for power at the power side of the fuse. The ignition switch and lights may have to be on before some fuses receive power. If the fuse is good, the test light should light on both sides (power side and load side) of the fuse.
M
(a) FUSE BLOCK
6 AMP CIRCUIT BREAKER
30 AMP CIRCUIT BREAKER
BIMETALLIC STRIP
CONTACTS CLOSED
CURRENT FLOW
FIGURE 44–8 Typical blade circuit breaker fits into the same space as a blade fuse. If excessive current flows through the bimetallic strip, the strip bends and opens the contacts and stops current flow. When the circuit breaker cools, the contacts close again, completing the electrical circuit.
M
(b)
FIGURE 44–10 (a) The normal operation of a PTC circuit protector such as in a power window motor circuit showing the many conducting paths. With normal current flow, the temperature of the PTC circuit protector remains normal. (b) When current exceeds the amperage rating of the PTC circuit protector, the polymer material that makes up the electronic circuit protector increases in resistance. As shown, a high-resistance electrical path still exists even though the motor will stop operating as a result of the very low current flow through the very high resistance. The circuit protector will not reset or cool down until voltage is removed from the circuit.
disastrous results. A circuit breaker opens and closes the circuit rapidly, thereby protecting the circuit from overheating and also providing sufficient current flow to maintain at least partial headlight operation. Circuit breakers are also used in other circuits where conventional fuses could not provide for the surges of high current commonly found in those circuits. SEE FIGURE 44–9 for the electrical symbols used to represent a circuit breaker. Examples are the circuits for the following accessories. 1. Power seats
CIRCUIT BREAKERS
Circuit breakers are used to prevent harmful overload (excessive current flow) in a circuit by opening the circuit and stopping the current flow to prevent overheating and possible fire caused by hot wires or electrical components. Circuit breakers are mechanical units made of two different metals (bimetallic) that deform when heated and open a set of contact points that work in the same manner as an “off” switch. SEE FIGURE 44–8. Cycling-type circuit breakers, therefore, are reset when the current stops flowing, which causes the bimetallic strip to cool and the circuit to close again. A circuit breaker is used in circuits that could affect the safety of passengers if a conventional nonresetting fuse were used. The headlight circuit is an excellent example of the use of a circuit breaker rather than a fuse. A short or grounded circuit anywhere in the headlight circuit could cause excessive current flow and, therefore, the opening of the circuit. Obviously, a sudden loss of headlights at night could have
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2. Power door locks 3. Power windows
PTC CIRCUIT PROTECTORS
Positive temperature coefficient (PTC) circuit protectors are solid state (without moving parts). Like all other circuit protection devices, PTCs are installed in series in the circuit being protected. If excessive current flows, the temperature and resistance of the PTC increase. This increased resistance reduces current flow (amperes) in the circuit and may cause the electrical component in the circuit not to function correctly. For example, when a PTC circuit protector is used in a power window circuit, the increased resistance causes the operation of the power window to be much slower than normal. Unlike circuit breakers or fuses, PTC circuit protection devices do not open the circuit, but rather provide a very high resistance between the protector and the component. SEE FIGURE 44–10.
JUNCTION BLOCK FUSIBLE LINKS
BATTERY CABLE (TO + TERMINAL OF BATTERY)
FIGURE 44–11 PTC circuit protectors are used extensively in the power distribution center of this Chrysler vehicle.
In other words, voltage will be available to the component. This fact has led to a lot of misunderstanding about how these circuit protection devices actually work. It is even more confusing when the circuit is opened and the PTC circuit protector cools down. When the circuit is turned back on, the component may operate normally for a short time; however, the PTC circuit protector will again get hot because of too much current flow. Its resistance again increases to limit current flow. The electronic control unit (computer) used in most vehicles today incorporates thermal overload protection devices. SEE FIGURE 44–11. Therefore, when a component fails to operate, do not blame the computer. The current control device is controlling current flow to protect the computer. Components that do not operate correctly should be checked for proper resistance and current draw.
FIGURE 44–12 Fusible links are usually located close to the battery and are usually attached to a junction block. Notice that they are only 6 to 9 in. long and feed more than one fuse from each fusible link.
FIGURE 44–13 A 125 ampere rated mega fuse used to control the current from the alternator.
TECH TIP Find the Root Cause
FUSIBLE LINKS
A fusible link is a type of fuse that consists of a short length (6 to 9 in. long) of standard copper-strand wire covered with a special nonflammable insulation. This wire is usually four wire numbers smaller than the wire of the circuits it protects. For example, a 12 gauge circuit is protected by a 16 gauge fusible link. The special thick insulation over the wire may make it look larger than other wires of the same gauge number. SEE FIGURE 44–12. If excessive current flow (caused by a short-to-ground or a defective component) occurs, the fusible link will melt in half and open the circuit to prevent a fire hazard. Some fusible links are identified with “fusible link” tags at the junction between the fusible link and the standard chassis wiring, which represent only the junction. Fusible links are the backup system for circuit protection. All current except the current used by the starter motor flows through fusible links and then through individual circuit fuses. It is possible that a fusible link will melt and not blow a fuse. Fusible links are installed as close to the battery as possible so that they can protect the wiring and circuits coming directly from the battery.
If a mega fuse or fusible link fails, find the root cause before replacing it. A mega fuse can fail due to vibration or physical damage as a result of a collision or corrosion. Check to see if the fuse itself is loose and can be moved by hand. If loose, then simply replace the mega fuse. If a fusible link or mega fuse has failed due to excessive current, check for evidence of a collision or any other reason that could cause an excessive amount of current to flow. This inspection should include each electrical component being supplied current from the fusible link. After being sure that the root cause has been found and corrected, then replace the fusible link or mega fuse.
Multiple circuits usually protected by mega fuses
Mega fuse rating for vehicles, including 80, 100, 125, 150, 175, 200, 225, and 250 amperes
SEE FIGURE 44–13.
MEGA FUSES
Many newer vehicles are equipped with mega fuses instead of fusible links to protect high-amperage circuits. Circuits often controlled by mega fuses include:
CHECKING FUSIBLE LINKS AND MEGA FUSES
Fusible links and mega fuses are usually located near where electrical power is sent to other fuses or circuits, such as:
Charging circuit
HID headlights
Starter solenoid battery terminals
Heated front or rear glass
Power distribution centers
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Output terminals of alternators
Positive terminals of the battery
SEAL
Fusible links can melt and not show any external evidence of damage. To check a fusible link, gently pull on each end to see if it stretches. If the insulation stretches, then the wire inside has melted and the fusible link must be replaced after determining what caused the link to fail. Another way to check a fusible link is to use a test light or a voltmeter and check for available voltage at both ends of the fusible link. If voltage is available at only one end, then the link is electrically open and should be replaced.
REPLACING A FUSIBLE LINK
CRIMP AND SOLDER
CRIMP
SEAL
CORE CRIMP
FIGURE 44–14 Some terminals have seals attached to help seal the electrical connections.
If a fusible link is found to be
melted, perform the following steps. STEP 1
Determine why the fusible link failed and repair the fault.
STEP 2
Check service information for the exact length, gauge, and type of fusible link required.
STEP 3
Replace the fusible link with the specified fusible link wire and according to the instructions found in the service information. CAUTION: Always use the exact length of fusible link wire required because if it is too short, it will not have enough resistance to generate the heat needed to melt the wire and protect the circuits or components. If the wire is too long, it could melt during normal operation of the circuits it is protecting. Fusible link wires are usually longer than 6 in. and shorter than 9 in.
SECONDARY LOCKS CLOSED
FIGURE 44–15 Separate a connector by opening the lock and pulling the two apart.
SECONDARY LOCKS OPEN
TERMINALS AND CONNECTORS
FIGURE 44–16 The secondary locks help retain the terminals in the connector.
TECH TIP A terminal is a metal fastener attached to the end of a wire, which makes the electrical connection. The term connector usually refers to the plastic portion that snaps or connects together, thereby making the mechanical connection. Wire terminal ends usually snap into and are held by a connector. Male and female connectors can then be snapped together, thereby completing an electrical connection. Connectors exposed to the environment are also equipped with a weather-tight seal. SEE FIGURE 44–14. Terminals are retained in connectors by the use of a lock tang. Removing a terminal from a connector includes the following steps. STEP 1
Release the connector position assurance (CPA), if equipped, that keeps the latch of the connector from releasing accidentally.
STEP 2
Separate the male and female connector by opening the lock. SEE FIGURE 44–15.
STEP 3
Release the secondary lock, if equipped. SEE FIGURE 44–16.
STEP 4
Using a pick, look for the slot in the plastic connector where the lock tang is located, depress the lock tang, and gently remove the terminal from the connector. SEE FIGURE 44–17.
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Look for the “Green Crud” Corroded connections are a major cause of intermittent electrical problems and open circuits. The usual sequence of conditions is as follows: 1. Heat causes expansion. This heat can be from external sources such as connectors being too close to the exhaust system. Another possible source of heat is a poor connection at the terminal, causing a voltage drop and heat due to the electrical resistance. 2. Condensation occurs when a connector cools. The moisture in the condensation causes rust and corrosion. 3. Water gets into the connector. The solution is, if corroded connectors are noticed, the terminal should be cleaned and the condition of the electrical connection to the wire terminal end(s) confirmed. Many vehicle manufacturers recommend using a dielectric silicone or lithium-based grease inside connectors to prevent moisture from getting into and attacking the connector.
TOOL
RAISING RETAINING FINGERS TO REMOVE CONTACTS
FIGURE 44–18 Always use rosin-core solder for electrical or electronic soldering. Also, use small-diameter solder for small soldering irons. Use large-diameter solder only for large-diameter (large-gauge) wire and higher-wattage soldering irons (guns).
LOCKING WEDGE CONNECTOR PLASTIC SPRING
LATCHING TONGUE
TERMINAL REMOVAL TOOL (PICK)
PLASTIC SPRING
LATCHING TONGUE
TANG CONNECTOR
FIGURE 44–17 Use a small removal tool, sometimes called a pick, to release terminals from the connector.
WIRE REPAIR SOLDER
Many manufacturers recommend that all wiring repairs be soldered. Solder is an alloy of tin and lead used to make a good electrical contact between two wires or connections in an electrical circuit. However, a flux must be used to help clean the area and to help make the solder flow. Therefore, solder is made with a resin (rosin) contained in the center, called rosin-core solder.
CAUTION: Never use acid-core solder to repair electrical wiring as the acid will cause corrosion.
SEE FIGURE 44–18.
FIGURE 44–19 A butane-powered soldering tool. The cap has a built-in striker to light a converter in the tip of the tool. This handy soldering tool produces the equivalent of 60 watts of heat. It operates for about 1/2 hour on one charge from a commonly available butane refill dispenser. An acid-core solder is also available but should only be used for soldering sheet metal. Solder is available with various percentages of tin and lead in the alloy. Ratios are used to identify these various types of solder, with the first number denoting the percentage of tin in the alloy and the second number giving the percentage of lead. The most commonly used solder is 50/50, which means that 50% of the solder is tin and the other 50% is lead. The percentages of each alloy primarily determine the melting point of the solder.
60/40 solder (60% tin/40% lead) melts at 361°F (183°C).
50/50 solder (50% tin/50% lead) melts at 421°F (216°C).
40/60 solder (40% tin/60% lead) melts at 460°F (238°C).
NOTE: The melting points stated here can vary depending on the purity of the metals used. Because of the lower melting point, 60/40 solder is the most highly recommended solder to use, followed by 50/50.
SOLDERING GUNS
When soldering wires, be sure to heat the wires (not the solder) using:
An electric soldering gun or soldering pencil (60 to 150 watt rating)
Butane-powered tool that uses a flame to heat the tip (about 60 watt rating)
SEE FIGURE 44–19.
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FLATTENED
CUTTING AREA
STRIPPING AREA
COMPRESSED
UPPER JAW
LOWER JAW
WIRE
TERMINAL TABS
FIGURE 44–20 Notice that to create a good crimp the open part of the terminal is placed in the jaws of the crimping tool toward the anvil or the W-shape part.
FIGURE 44–22 A butane torch especially designed for use on heat shrink applies heat without an open flame, which could cause damage.
SHINY APPEARANCE
FIGURE 44–21 All hand-crimped splices or terminals should be soldered to be assured of a good electrical connection.
SOLDERING PROCEDURE
Soldering a wiring splice includes
the following steps. STEP 1
While touching the soldering gun to the splice, apply solder to the junction of the gun and the wire.
STEP 2
The solder will start to flow. Do not move the soldering gun.
STEP 3
Just keep feeding more solder into the splice as it flows into and around the strands of the wire.
STEP 4
After the solder has flowed throughout the splice, remove the soldering gun and the solder from the splice and allow the solder to cool slowly.
The solder should have a shiny appearance. Dull-looking solder may be caused by not reaching a high enough temperature, which results in a cold solder joint. Reheating the splice and allowing it to cool often restores the shiny appearance.
CRIMPING TERMINALS Terminals can be crimped to create a good electrical connection if the proper type of crimping tool is used. Most vehicle manufacturers recommend that a W-shaped crimp be used to force the strands of the wire into a tight space. SEE FIGURE 44–20. Most vehicle manufacturers also specify that all hand-crimped terminals or splices be soldered. SEE FIGURE 44–21.
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FIGURE 44–23 A typical crimp-and-seal connector. This type of connector is first lightly crimped to retain the ends of the wires and then it is heated. The tubing shrinks around the wire splice, and thermoplastic glue melts on the inside to provide an effective weather-resistant seal.
HEAT SHRINK TUBING Heat shrink tubing is usually made from polyvinyl chloride (PVC) or polyolefin and shrinks to about half of its original diameter when heated; this is usually called a 2:1 shrink ratio. Heat shrink by itself does not provide protection against corrosion, because the ends of the tubing are not sealed against moisture. DaimlerChrysler Corporation recommends that all wire repairs that may be exposed to the elements be repaired and sealed using adhesive-lined heat shrink tubing. The tubing is usually made from flame-retardant flexible polyolefin with an internal layer of special thermoplastic adhesive. When heated, this tubing shrinks to onethird of its original diameter (3:1 shrink ratio) and the adhesive melts and seals the ends of the tubing. SEE FIGURE 44–22. CRIMP-AND-SEAL CONNECTORS
General Motors Corporation recommends the use of crimp-and-seal connectors as the method for wire repair. Crimp-and-seal connectors contain a sealant and shrink tubing in one piece and are not simply butt connectors. SEE FIGURE 44–23. The usual procedure specified for making a wire repair using a crimp-and-seal connector is as follows: STEP 1
Strip the insulation from the ends of the wire (about 5/16 in., or 8 mm).
FIGURE 44–24 Heating the crimp-and-seal connector melts the glue and forms an effective seal against moisture.
?
FIGURE 44–25 Conduit that has a paint strip is constructed of plastic that can withstand high underhood temperatures.
?
FREQUENTLY ASKED QUESTION
What Is in Lead-Free Solder?
What Method of Wire Repair Should I Use?
Lead is an environmental and a health concern and all vehicle manufacturers are switching to lead-free solder. Lead free solder does not contain lead but usually a very high percentage of tin. Several formulations of lead-free solder include:
Good question. Vehicle manufacturers recommend all wire repairs performed under the hood, or where the repair could be exposed to the elements, be weatherproof. The most commonly recommended methods include: • Crimp and seal connector. These connectors are special and are not like low cost insulated-type crimp connectors. This type of connector is recommended by General Motors and others and is sealed using heat after the mechanical crimp has secured the wire ends together. • Solder and adhesive-lined heat shrink tubing. This method is recommended by Chrysler and it uses the special heat shrink that has glue inside that melts when heated to form a sealed connection. Regular heat shrink tubing can be used inside a vehicle, but should not be used where it can be exposed to the elements. • Solder and electrical tape. This is acceptable to use inside the vehicle where the splice will not be exposed to the outside elements. It is best to use a crimp and seal even on the inside of the vehicle for best results.
STEP 2
Select the proper size of crimp-and-seal connector for the gauge of wire being repaired. Insert the wires into the splice sleeve and crimp.
• 95% Tin; 5% Antimony (melting temperature 450°F (245°C) • 97% Tin; 3% Copper (melting temperature 441°F (227°C) • 96% Tin; 4% Silver (melting temperature 443°F (228°C)
If any aluminum wire must be repaired or replaced, the following procedure should be used to be assured of a proper repair. The aluminum wire is usually found protected in a plastic conduit. This conduit is then normally slit, after which the wires can easily be removed for repair. STEP 1
Carefully strip only about 1/4 in. (6 mm) of insulation from the aluminum wire, being careful not to nick or damage the aluminum wire case.
STEP 2
Use a crimp connector to join two wires together. Do not solder an aluminum wire repair. Solder will not readily adhere to aluminum because the heat causes an oxide coating on the surface of the aluminum.
STEP 3
The spliced, crimped connection must be coated with petroleum jelly to prevent corrosion.
STEP 4
The coated connection should be covered with shrinkable plastic tubing or wrapped with electrical tape to seal out moisture.
NOTE: Only use the specified crimping tool to help prevent the pliers from creating a hole in the cover. STEP 3
Apply heat to the connector until the sleeve shrinks down around the wire and a small amount of sealant is observed around the ends of the sleeve, as shown in FIGURE 44–24.
ALUMINUM WIRE REPAIR
Some vehicle manufacturers used plastic-coated solid aluminum wire for some body wiring. Because aluminum wire is brittle and can break as a result of vibration, it is only used where there is no possible movement of the wire, such as along the floor or sill area. This section of wire is stationary, and the wire changes back to copper at a junction terminal after the trunk or rear section of the vehicle, where movement of the wiring may be possible.
FREQUENTLY ASKED QUESTION
ELECTRICAL CONDUIT Electrical conduit covers and protects wiring. The color used on electrical convoluted conduit tells the technician a lot if some information is known, such as the following:
Black conduit with a green or blue stripe. This conduit is designed for high temperatures and is used under the hood and near hot engine parts. Do not replace high-temperature conduit with low-temperature conduit that does not have a stripe when performing wire repairs. SEE FIGURE 44–25.
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(a)
(b)
FIGURE 44–26 (a) Blue conduit is used to cover circuits that carry up to 42 volts. (b) Yellow conduit can also be used to cover 42 volt wiring.
Blue or yellow conduit. This color conduit is used to cover wires that have voltages ranging from 12 to 42 volts. Circuits that use this high voltage usually are for the electric power steering. While 42 volts does not represent a shock hazard, an arc will be maintained if a line circuit is disconnected. Use caution around these circuits. SEE FIGURE 44–26.
Orange conduit. This color conduit is used to cover wiring that carries high-voltage current from 144 to 650 volts. These circuits are found in hybrid electric vehicles (HEVs). An electric shock from these wires can be fatal, so extreme caution has to be taken when working on or near the components that have orange conduit. Follow the vehicle manufacturer’s instruction for de-powering the high-voltage circuits before work begins on any of the high-voltage components. SEE FIGURE 44–27.
FIGURE 44–27 Always follow the vehicle manufacturer’s instructions which include the use of linesman’s (high-voltage) gloves if working on circuits that are covered in orange conduit.
REVIEW QUESTIONS 1. What is the difference between the American wire gauge (AWG) system and the metric system?
4. How do fuses, PTC circuit protectors, circuit breakers, and fusible links protect a circuit?
2. What is the difference between a wire and a cable?
5. How should a wire repair be done if the repair is under the hood where it is exposed to the outside?
3. What is the difference between a terminal and a connector?
CHAPTER QUIZ 1. The higher the AWG number, ______________. a. The smaller the wire diameter b. The larger the wire diameter c. The thicker the insulation d. The more strands in the conductor core 2. Metric wire size is measured in units of ______________. a. Meters c. Square millimeters b. Cubic centimeters d. Cubic millimeters
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3. Which statement is true about fuse ratings? a. The fuse rating should be less than the maximum current for the circuit. b. The fuse rating should be higher than the normal current for the circuit. c. Of the fuse rating, 80% should equal the current in the circuit. d. Both b and c
4. Which statements are true about wire, terminals, and connectors? a. Wire is called a lead, and the metal end is a connector. b. A connector is usually a plastic piece where terminals lock in. c. A lead and a terminal are the same thing. d. Both a and c 5. The type of solder that should be used for electrical work is ______________. a. Rosin core c. 60/40 with no flux b. Acid core d. 50/50 with acid paste flux 6. A technician is performing a wire repair on a circuit under the hood of the vehicle. Technician A says to use solder and adhesive-lined heat shrink tubing or a crimp and seal connector. Technician B says to solder and use electrical tape. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 7. Two technicians are discussing fuse testing. Technician A says that a test light should light on both test points of the fuse if it is okay. Technician B says the fuse is defective if a test light only lights on one side of the fuse. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
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45
8. What is true about the plastic conduit covering the wiring? a. The color stripe is used to identify the temperature rating of the conduit b. The color identifies the voltage level of the circuits being protected. c. Protects the wiring. d. All of the above 9. Many ground straps are uninsulated and braided because ______________. a. They are more flexible to allow movement of the engine without breaking the wire. b. They are less expensive than conventional wire. c. They help dampen radio-frequency interference (RFI). d. Both a and c 10. What causes a fuse to blow? a. A decrease in circuit resistance b. An increase in the current flow through the circuit c. A sudden decrease in current flow through the circuit d. Both a and b
WIRING SCHEMATICS AND CIRCUIT TESTING
OBJECTIVES: After studying Chapter 45, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A“ (General Electrical/Electronics System Diagnosis). • Interpret wiring schematics. • Explain how relays work. • Discuss the various methods that can be used to locate a short circuit. • List the electrical troubleshooting diagnosis steps. KEY TERMS: Coil 485 • DPDT 484 • DPST 484 • Gauss gauge 490 • Momentary switch 484 • N.C. 484 • N.O. 484 • Poles 484 • Relay 485 • Short circuit 489 • SPDT 484 • SPST 484 • Terminal 480 • Throws 484 • Tone generator tester 490 • Wiring schematic 479
WIRING SCHEMATICS AND SYMBOLS TERMINOLOGY The service manuals of automotive manufacturers include wiring schematics of every electrical circuit in a vehicle. A wiring schematic, sometimes called a diagram, shows electrical components and wiring using symbols and lines to represent components and wires. A typical wiring schematic may include all of the circuits combined on several large foldout sheets, or they may be broken down to show individual circuits. All circuit schematics or diagrams include:
Power-side wiring of the circuit
All splices
Connectors
Wire size
Wire color
Trace color (if any)
Circuit number
Electrical components
Ground return paths
Fuses and switches
CIRCUIT INFORMATION
Many wiring schematics include numbers and letters near components and wires that may confuse readers of the schematic. Most letters used near or on a wire identify the color or colors of the wire.
The first color or color abbreviation is the color of the wire insulation.
The second color (if mentioned) is the color of the stripe or tracer on the base color. SEE FIGURE 45–1.
W I RI N G SC H E MAT I C S AN D C I RC U IT T ES T IN G
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C-210 0.8 PPL
0.8 PPL/WHT RH REAR MARKER LIGHT
FIGURE 45–1 The center wire is a solid color wire, meaning that the wire has no other identifying tracer or stripe color. The two end wires could be labeled “BRN/WHT,” indicating a brown wire with a white tracer or stripe.
0.8 BLK
FIGURE 45–2 Typical section of a wiring diagram. Notice that the wire color changes at connection C210. The “.8” represents the metric wire size in square millimeters.
ABBREVIATION
COLOR
BRN
Brown
BLK
Black
GRN
Green
WHT
White
PPL
Purple
Read the Arrows
PNK
Pink
TAN
Tan
BLU
Blue
YEL
Yellow
ORN
Orange
DK BLU
Dark blue
LT BLU
Light blue
Wiring diagrams indicate connections by symbols that look like arrows. SEE FIGURE 45–4 on page 481. Do not read these “arrows” as pointers showing the direction of current flow. Also observe that the power side (positive side) of the circuit is usually the female end of the connector. If a connector becomes disconnected, it will be difficult for the circuit to become shorted to ground or to another circuit because the wire is recessed inside the connector.
DK GRN
Dark green
LT GRN
Light green
RED
Red
GRY
Gray
VIO
Violet
CHART 45–1 Typical abbreviations used on schematics to show wire color. Some vehicle manufacturers use two letters to represent a wire color. Check service information for the color abbreviations used. Wires with different color tracers are indicated by both colors with a slash (/) between them. For example, BRN/WHT means a brown wire with a white stripe or tracer. SEE CHART 45–1.
WIRE SIZE Wire size is shown on all schematics. FIGURE 45–2 illustrates a rear side-marker bulb circuit diagram where “.8” indicates the metric wire gauge size in square millimeters (mm2) and “PPL” indicates a solid purple wire. The wire diagram also shows that the color of the wire changes at the number C210. This stands for “connector #210” and is used for reference purposes. The symbol for the connection can vary depending on the manufacturer. The color change from purple (PPL) to purple with a white tracer (PPL/WHT) is not important except for knowing where the wire changes color in the circuit. The wire gauge has remained the same on both sides of the connection (0.8 mm2 or 18 gauge). The ground circuit is the “.8 BLK” wire. FIGURE 45–3 shows many of the electrical and electronic symbols that are used in wiring and circuit diagrams.
TECH TIP
BATTERY The plates of a battery are represented by long and short lines. SEE FIGURE 45–5. The longer line represents the positive plate of a battery and the shorter line represents the negative plate of the battery. Therefore, each pair of short and long lines represents one cell of a battery. Because each cell of a typical automotive lead-acid battery has 2.1 volts, a battery symbol showing a 12 volt battery should have six pairs of lines. However, most battery symbols simply use two or three pairs of long and short lines and then list the voltage of the battery next to the symbol. As a result, the battery symbols are shorter and yet clear, because the voltage is stated. The positive terminal of the battery is often indicated with a plus sign (⫹), representing the positive post of the battery, and is placed next to the long line of the end cell. The negative terminal of the battery is represented by a negative sign (⫺) and is placed next to the shorter cell line. The negative battery terminal is connected to ground. SEE FIGURE 45–6. WIRING
Electrical wiring is shown as straight lines and with a few numbers and/or letters to indicate the following:
Wire size. This can be either AWG, such as 18 gauge, or in square millimeters, such as 0.8 mm2.
Circuit numbers. Each wire in part of a circuit is labeled with the circuit number to help the service technician trace the wiring and to provide an explanation of how the circuit should work.
Wire color. Most schematics also indicate an abbreviation for the color of the wire and place it next to the wire. Many wires have two colors: a solid color and a stripe color. In this case, the solid color is listed, followed by a dark slash (/) and the color of the stripe. For example, Red/Wht would indicate a red wire with a white tracer. SEE FIGURE 45–7.
Terminals. The metal part attached at the end of a wire is called a terminal. A symbol for a terminal is shown in FIGURE 45–8.
SCHEMATIC SYMBOLS In a schematic drawing, photos or line drawings of actual components are replaced with a symbol that represents the actual component. The following discussion centers on these symbols and their meanings.
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OR
POSITIVE
DIODE
NEGATIVE
ZENER DIODE
BATTERY
LIGHT-EMITTING DIODE (LED)
OR
GROUND
CAPACITOR
MOTOR
FUSE
CIRCUIT BREAKER
CASE GROUNDED
RESISTOR
VARIABLE RESISTOR
VARIABLE RESISTOR (POTENTIOMETER)
SOLID BOX REPRESENTS ENTIRE COMPONENT DASHED LINE REPRESENTS PORTION (PART) OF A COMPONENT
BULB (LAMP) NORMALLY OPEN (N.O.) RELAY DUAL-FILAMENT BULB
MALE TERMINAL
NORMALLY CLOSED (N.C.) RELAY
FEMALE TERMINAL CONNECTOR DELTA (
) WINDINGS
SPLICE
WIRES NOT ELECTRONICALLY CONNECTED WYE (Y) WINDINGS COIL WINDING
COIL WITH STEEL LAMINATIONS
FIGURE 45–3 Typical electrical and electronic symbols used in automotive wiring and circuit diagrams.
TO BATTERY
TO ELECTRICAL COMPONENT
FIGURE 45–4 In this typical connector, note that the positive terminal is usually a female connector.
FIGURE 45–5 The symbol for a battery. The positive plate of a battery is represented by the longer line and the negative plate by the shorter line. The voltage of the battery is usually stated next to the symbol.
481
OR
FIGURE 45–6 The ground symbol on the left represents earth ground. The ground symbol on the right represents a chassis ground.
100-199 UNDER HOOD
200-299 UNDER DASH
300-399 INSIDE PASSENGER COMPARTMENT
400-499 TRUNK
HOT AT ALL TIMES
IGNITION SWITCH
START
B
FIGURE 45–11 Connectors (C), grounds (G), and splices (S) are followed by a number, generally indicating the location in the vehicle. For example, G209 is a ground connection located under the dash.
C2 32 BLK 1
0.5 YEL 5
BATTERY B3
C202
0.5 YEL 5
B6
GROUND DISTRIBUTION SCHEMATICS IN WIRING SYSTEMS
C101
BLK 50
32 BLK 50
FIGURE 45–7 Starting at the top, the wire from the ignition switch is attached to terminal B of connector C2, the wire is 0.5 mm2 (20 gauge AWG), and is yellow. The circuit number is 5. The wire enters connector C202 at terminal B3. G305
FIGURE 45–12 The ground for the battery is labeled G305 indicating the ground connector is located in the passenger compartment of the vehicle. The ground wire is black (BLK), the circuit number is 50, and the wire is 32 mm2 (2 gauge AWG).
B
A
FIGURE 45–8 The electrical terminals are usually labeled with a letter or number.
SPLICE
FIGURE 45–9 Two wires that cross at the dot indicate that the two are electrically connected. WIRES NOT ELECTRONICALLY CONNECTED
Splices. When two wires are electrically connected, the junction is shown with a black dot. The identification of the splice is an “S” followed by three numbers, such as S103. SEE FIGURE 45–9. When two wires cross in a schematic that are not electrically connected, one of the wires is shown as going over the other wire and does not connect. SEE FIGURE 45–10. Connectors. An electrical connector is a plastic part that contains one or more terminals. Although the terminals provide the electrical connection in a circuit, it is the plastic connector that keeps the terminals together mechanically.
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100 to 199
Under the hood
200 to 299
Under the dash
300 to 399
Passenger compartment
400 to 499
Rear package or trunk area
500 to 599
Left-front door
600 to 699
Right-front door
700 to 799
Left-rear door
800 to 899
Right-rear door
Even-numbered connectors are on the right (passenger side) of the vehicle and odd-numbered connectors are on the left (driver’s side) of the vehicle. For example, C102 is a connector located under the hood (between 100 and 199) on the right side of the vehicle (even number 102). SEE FIGURE 45–11.
FIGURE 45–10 Wires that cross, but do not electrically contact each other, are shown with one wire bridging over the other.
Location. Connections are usually labeled “C” and then three numbers. The three numbers indicate the general location of the connector. Normally, the connector number represents the general area of the vehicle, including:
Grounds and splices. These are also labeled using the same general format as connectors. Therefore, a ground located under the dash on the driver’s side could be labeled G305 (G means “ground” and the “305” means that it is located in the passenger compartment). SEE FIGURE 45–12.
ELECTRICAL COMPONENTS Most electrical components have their own unique symbol that shows the basic function or parts.
BULB (LAMP) OR
DUAL-FILAMENT BULB (LAMP)
FIGURE 45–13 The symbol for light bulbs shows the filament inside a circle, which represents the glass ampoule of the bulb.
FIGURE 45–17 Symbols used to represent capacitors. If one of the lines is curved, this indicates that the capacitor being used has a polarity, while the one without a curved line can be installed in the circuit without concern about polarity.
B LIGHTER M
FIGURE 45–18 The gridlike symbol represents an electrically heated element. This symbol is used to represent a cigarette lighter or a heated rear window (rear window defogger)
A
FIGURE 45–14 An electric motor symbol shows a circle with the letter M in the center and two black sections that represent the brushes of the motor. This symbol is used even though the motor is a brushless design.
RESISTOR
FIGURE 45–19 A dashed outline represents a portion (part) of a component.
VARIABLE RESISTOR
FIGURE 45–20 A solid box represents an entire component. VARIABLE RESISTOR (POTENTIOMETER)
FIGURE 45–15 Resistor symbols vary depending on the type of resistor.
FIGURE 45–16 A rheostat uses only two wires—one is connected to a voltage source and the other is attached to the movable arm.
Bulbs. Light bulbs often use a filament, which heats and then gives off light when electrical current flows. The symbol used for a light bulb is a circle with a filament inside. A dualfilament bulb, such as is used for taillights and brake light/turn signals, is shown with two filaments. SEE FIGURE 45–13.
ELECTRIC MOTORS An electric motor symbol shows a circle with the letter M in the center and two electrical connections, one to the top and one at the bottom. SEE FIGURE 45–14 for an example of a cooling fan motor. RESISTORS Although resistors are usually part of another component, the symbol appears on many schematics and wiring diagrams. A resistor symbol is a jagged line representing resistance to current flow. If the resistor is variable, such as a thermistor, an arrow is shown running through the symbol of a fixed resistor. A potentiometer is a three-wire variable resistor, shown with an arrow pointing toward the resistance part of a fixed resistor. SEE FIGURE 45–15. A two-wire rheostat is usually shown as part of another unit, such as a fuel level sending unit. SEE FIGURE 45–16.
CAPACITORS Capacitors are usually part of an electronic component, but not a replaceable component unless the vehicle is an older model. Many older vehicles used capacitors to reduce radio interference and were installed inside alternators inside alternators or attached to or attached to wiring connectors. SEE FIGURE 45–17. ELECTRIC HEATED UNIT Electric grid-type rear window defoggers and cigarette lighters are shown with a square box-type symbol. SEE FIGURE 45–18. BOXED COMPONENTS If a component is shown in a box using a solid line, the box is the entire component. If a box uses dashed lines, it represents part of a component. A commonly used dashedline box is a fuse panel. Often, just one or two fuses are shown in a dashed-line box. This means that a fuse panel has more fuses than shown. SEE FIGURES 45–19 AND 45–20. SEPARATE REPLACEABLE PART
Often components are shown on a schematic that cannot be replaced, but are part of a complete assembly. When looking at a schematic of General Motors vehicles, the following is shown.
If a part name is underlined, it is a replaceable part.
If a part is not underlined, it is not available as a replaceable part, but is included with other components shown and sold as an assembly.
If the case itself is grounded, the ground symbol is attached to the component as shown in FIGURE 45–21.
SWITCHES
Electrical switches are drawn on a wiring diagram in their normal position. This can be one of two possible positions.
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FIGURE 45–21 This symbol represents a component that is case grounded.
Normally open. The switch is not connected to its internal contacts and no current will flow. This type of switch is labeled N.O.
SPST
SPDT
Normally closed. The switch is electrically connected to its internal contacts and current will flow through the switch. This type of switch is labeled N.C.
(a)
(b)
Other switches can use more than two contacts. The poles refer to the number of circuits completed by the switch and the throws refer to the number of output circuits. A single-pole, single-throw (SPST) switch has only two positions, on or off. A single-pole, double-throw (SPDT) switch has three terminals, one wire in and two wires out. A headlight dimmer switch is an example of a typical SPDT switch. In one position, the current flows to the low-filament headlight; in the other, the current flows to the high-filament headlight. NOTE: A SPDT switch is not an on or off type of switch but instead directs power from the source to either the highbeam lamps or the low-beam lamps. There are also double-pole, single-throw (DPST) switches and double-pole, double-throw (DPDT) switches. SEE FIGURE 45–22. NOTE: All switches are shown on schematics in their normal position. This means that the headlight switch will be shown normally off, as are most other switches and controls.
MOMENTARY SWITCH A momentary switch is a switch primarily used to send a voltage signal to a module or controller to request that a device be turned on or off. The switch makes momentary contact and then returns to the open position. A horn switch is a commonly used momentary switch. The symbol that represents a momentary switch uses two dots for the contact with a switch above them. A momentary switch can be either normally open or normally closed. SEE FIGURE 45–23.
DPDT
DPST
(c)
(d)
FIGURE 45–22 (a) A symbol for a single-pole, single-throw (SPST) switch. This type of switch is normally open (N.O.) because nothing is connected to the terminal that the switch is contacting in its normal position. (b) A single-pole, double-throw (SPDT) switch has three terminals. (c) A double-pole, single-throw (DPST) switch has two positions (off and on) and can control two separate circuits. (d) A double-pole, double-throw (DPDT) switch has six terminals—three for each pole. Note: Both (c) and (d) also show a dotted line between the two arms indicating that they are mechanically connected, called a “ganged switch”.
TECH TIP (a)
Color-Coding Is Key to Understanding Whenever diagnosing an electrical problem, it is common practice to print out the schematic of the circuit and then take it to the vehicle. A meter is then used to check for voltage at various parts of the circuit to help determine where there is a fault. The diagnosis can be made easier if the parts of the circuit are first color coded using markers or color pencils. A color-coding system that has been widely used is one developed by Jorge Menchu (www.aeswave.com). The colors represent voltage conditions in various parts of a circuit. Once the circuit has been color coded, then the circuit can be tested using the factory wire colors as a guide. SEE FIGURE 45–24.
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(b)
FIGURE 45–23 (a) A symbol for a normally open (N.O.) momentary switch. (b) A symbol for a normally closed (N.C.) momentary switch.
A momentary switch, for example, can be used to lock or unlock a door or to turn the air conditioning on or off. If the device is currently operating, the signal from the momentary switch will turn it off, and if it is off, the switch will signal the module to turn it on. The major advantage of momentary switches is that they can be lightweight and small, because the switch does not carry any heavy electrical current, just a small voltage signal. Most momentary switches use a membrane constructed of foil and plastic.
FIGURE 45–24 Using a marker and color-coding the various parts of the circuit makes the circuit easier to understand and helps diagnosing electrical problems easier. (Courtesy of Jorge Menchu.) 86 87 87a
MOVABLE ARM (ARMATURE)
INSULATED STOP CONTACT POINTS
COIL 30 85
30
86 - POWER SIDE OF THE COIL 85 - GROUND SIDE OF THE COIL
(MOSTLY RELAY COILS HAVE BETWEEN 50–150 OHMS OF RESISTANCE)
30 - COMMON POWER FOR RELAY CONTACTS 87 - NORMALLY OPEN OUTPUT (N.O.) 87a - NORMALLY CLOSED OUTPUT (N.C.)
FIGURE 45–25 A relay uses a movable arm to complete a circuit whenever there is a power at terminal 86 and a ground at terminal 85. A typical relay only requires about 1/10 ampere through the relay coil. The movable arm then closes the contacts (#30 to #87) and can relay 30 amperes or more.
RELAY TERMINAL IDENTIFICATION DEFINITION
A relay is a magnetic switch that uses a movable armature to control a high-amperage circuit by using a lowamperage electrical switch.
ISO RELAY TERMINAL IDENTIFICATION Most automotive relays adhere to common terminal identification. The primary source for this common identification comes from the standards established by the International Standards Organization (ISO). Knowing this terminal information will help in the correct diagnosis and troubleshooting of any circuit containing a relay. SEE FIGURES 45–25 AND 45–26. Relays are found in many circuits because they are capable of being controlled by computers, yet are able to handle enough current to power motors and accessories. Relays include the following components and terminals.
87
86
85
FIGURE 45–26 A cross-sectional view of a typical four-terminal relay. Current flowing through the coil (terminals 86 and 85) causes the movable arm (called the armature) to be drawn toward the coil magnet. The contact points complete the electrical circuit connected to terminals 30 and 87.
RELAY OPERATION 1. Coil (terminals 85 and 86) A coil provides the magnetic pull to a movable armature (arm). The resistance of most relay coils ranges from 50 to 150 ohms, but is usually between 60 and 100 ohms. The ISO identification of the coil terminals are 86 and 85. The terminal number 86 represents the power to the relay coil and the terminal labeled 85 represents the ground side of the relay coil. The relay coil can be controlled by supplying either power or ground to the relay coil winding. The coil winding represents the control circuit which uses low current to control the higher current through the other terminals of the relay. SEE FIGURE 45–27. 2. Other terminals used to control the load current
The higher amperage current flow through a relay flows through terminals 30 and 87, and often 87a. Terminal 30 is usually where power is applied to a relay. Check service information for the exact operation of the relay being tested. When the relay is at rest without power and ground to the coil, the armature inside the relay electrically connects terminals 30 and 87a if the relay has five terminals. When
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RELAY
15A FUSE
RELAY SOCKET 2
HORN RELAY
1
3
4 2E
5 2A
10 HORN SWITCH
1 HORN LH
FIGURE 45–27 A typical relay showing the schematic of the wiring in the relay.
1 HORN RH
FIGURE 45–29 A typical horn circuit. Note that the relay contacts supply the heavy current to operate the horn when the horn switch simply completes a low-current circuit to ground, causing the relay contacts to close. TRANSISTOR (OFF) B+
NORMALLY OPEN (N.O.) RELAY
NORMALLY CLOSED (N.C.) RELAY
FIGURE 45–30 When the relay or solenoid coil current is turned off, the stored energy in the coil flows through the clamping diode and effectively reduces voltage spike.
FIGURE 45–28 All schematics are shown in their normal, nonenergized position.
RESISTOR COIL WINDING
there is power at terminal 85 and a ground at terminal 86 of the relay, a magnetic field is created in the coil winding, which draws the armature of the relay toward the coil. The armature, when energized electrically, connects terminals 30 and 87. The maximum current through the relay is determined by the resistance of the circuit, and relays are designed to safely handle the designed current flow. SEE FIGURES 45–28 AND 45–29.
RELAY VOLTAGE SPIKE CONTROL Relays contain a coil and when power is removed, the magnetic field surrounding the coil collapses, creating a voltage to be induced in the coil winding. This induced voltage can be as high as 100 volts or more and can cause problems with other electronic devices in the vehicle. For example, the short high-voltage surge can be heard as a “pop” in the radio. To reduce the induced voltage, some relays contain a diode connected across the coil. SEE FIGURE 45–30. When the current flows through the coil, the diode is not part of the circuit because it is installed to block current. However, when the voltage is removed from the coil, the resulting voltage induced in the coil windings has a reversed polarity to the applied voltage. Therefore, the voltage in the coil is applied to the coil in a forward direction through the diode, which conducts the current back into the winding. As a result, the induced voltage spike is eliminated.
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FIGURE 45–31 A resistor used in parallel with the coil windings is a common spike reduction method used in many relays. Most relays use a resistor connected in parallel with the coil winding. The use of a resistor, typically about 400 to 600 ohms, reduces the voltage spike by providing a path for the voltage created in the coil to flow back through the coil windings when the coil circuit is opened. SEE FIGURE 45–31.
LOCATING AN OPEN CIRCUIT TERMINOLOGY An open circuit is a break in the electrical circuit that prevents current from flowing and operating an electrical device. Examples of open circuits include:
Blown (open) light bulbs
Cut or broken wires
Disconnected or partially disconnected electrical connectors
TECH TIP
REAL WORLD FIX
Divide the Circuit in Half
The Electric Mirror Fault Story
When diagnosing any circuit that has a relay, start testing at the relay and divide the circuit in half.
Often, a customer will notice just one fault even though other lights or systems may not be working correctly. For example, a customer noticed that the electric mirrors stopped working. The service technician checked all electrical components in the vehicle and discovered that the interior lights were also not working. The interior lights were not mentioned by the customer as being a problem most likely because the driver only used the vehicle in daylight hours. The service technician found the interior light and power accessory fuse blown. Replacing the fuse restored the proper operation of the electric outside mirror and the interior lights. However, what caused the fuse to blow? A visual inspection of the dome light, next to the electric sunroof, showed an area where a wire was bare. Evidence showed the bare wire had touched the metal roof, which could cause the fuse to blow. The technician covered the bare wire with a section of vacuum hose and then taped the hose with electrical tape to complete the repair.
• High current portion: Remove the relay and check that there are 12 volts at the terminal 30 socket. If there is, then the power side is okay. Use an ohmmeter and check between terminal 87 socket and ground. If the load circuit has continuity, there should be some resistance. If OL, the circuit is electrically open. • Control circuit (low current): With the relay removed from the socket, check that there is 12 volts to terminal 86 with the ignition on and the control switch on. If not, check service information to see if power should be applied to terminal 86, then continue troubleshooting the switch power and related circuit. • Check the relay itself: Use an ohmmeter and measure for continuity and resistance. • Between terminals 85 and 86 (coil), there should be 60 to 100 ohms. If not, replace the relay. • Between terminals 30 and 87 (high-amperage switch controls), there should be continuity (low ohms) when there is power applied to terminal 85 and a ground applied to terminal 86 that operates the relay. If OL is displayed on the meter set to read ohms, the circuit is open which requires that the reply be replaced. • Between terminals 30 and 87a (if equipped), with the relay turned off, there should be low resistance (less than 5 ohms).
?
• Look for evidence of recent body damage or body repairs. Movement due to a collision can cause metal to move, which can cut wires or damage connectors or components. STEP 2
Print out the schematic. Trace the circuit and check for voltage at certain places. This will help pinpoint the location of the open circuit.
STEP 3
Check everything that does and does not work. Often, an open circuit will affect more than one component. Check the part of the circuit that is common to the other components that do not work.
STEP 4
Check for voltage. Voltage is present up to the location of the open circuit fault. For example, if there is battery voltage at the positive terminal and the negative (ground) terminal of a two-wire light bulb socket with the bulb plugged in, then the ground circuit is open.
FREQUENTLY ASKED QUESTION
What Is the Difference Between a Relay and a Solenoid? Often, these terms are used differently among vehicle manufacturers, which can lead to some confusion. Relay: A relay is an electromagnetic switch that uses a movable arm. Because a relay uses a movable arm, it is generally limited to current flow not exceeding 30 amperes. Solenoid: A solenoid is an electromagnetic switch that uses a movable core. Because of this type of design, a solenoid is capable of handling 200 amperes or more and is used in the starter motor circuit and other high-amperage applications, such as in the glow plug circuit of diesel engines.
Electrically open switches
Loose or broken ground connections or wires
Blown fuse
PROCEDURE TO LOCATE AN OPEN CIRCUIT
The typical procedure for locating an open circuit involves the following steps. STEP 1
Perform a thorough visual inspection. Check the following: • Look for evidence of a previous repair. Often, an electrical connector or ground connection can be accidentally left disconnected.
COMMON POWER OR GROUND When diagnosing an electrical problem that affects more than one component or system, check the electrical schematic for a common power source or a common ground. SEE FIGURE 45–32 for an example of lights being powered by one fuse (power source).
Underhood light
Inside lighted mirrors
Dome light
Left-side courtesy light
Right-side courtesy light
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ADDED RELAY
HOT AT ALL TIMES
ADDED FUSE
#14 COURTESY FUSE (15A)
UNDERHOOD LIGHT
LIGHT SWITCH (NORMALLY CLOSED WITH HOOD OPEN)
ADDED LIGHTS
BAT+
S201 SPLICE
RIGHT INSIDE LIGHTED MIRROR EXISTING LIGHT
S319
FIGURE 45–33 To add additional lighting, simply tap into an existing light wire and connect a relay. Whenever the existing light is turned on, the coil of the relay is energized. The arm of the relay then connects power from another circuit (fuse) to the auxiliary lights without overloading the existing light circuit.
LEFT INSIDE LIGHTED MIRROR
RIGHT SIDE COURTESY LIGHT
TECH TIP Do It Right—Install a Relay
S316
LEFT SIDE COURTESY LIGHT
LIGHT SWITCH S364 R H FRONT DOOR JAMB SWITCH S320 C101 DOME LIGHT
L H FRONT DOOR JAMB SWITCH
Often the owners of vehicles, especially owners of pickup trucks and sport utility vehicles (SUVs), want to add additional electrical accessories or lighting. It is tempting in these cases to simply splice into an existing circuit. However, when another circuit or component is added, the current that flows through the newly added component is also added to the current for the original component. This additional current can easily overload the fuse and wiring. Do not simply install a larger amperage fuse; the wire gauge size was not engineered for the additional current and could overheat. The solution is to install a relay, which uses a small coil to create a magnetic field that causes a movable arm to switch on a higher current circuit. The typical relay coil has from 50 to 150 ohms (usually 60 to 100 ohms) of resistance and requires just 0.24 to 0.08 ampere when connected to a 12 volt source. This small additional current will not be enough to overload the existing circuit. SEE FIGURE 45–33 for an example of how additional lighting can be added.
FIGURE 45–32 A typical wiring diagram showing multiple switches and bulbs powered by one fuse. Therefore, if a customer complains about one or more of the items listed, check the fuse and the common part of the circuit that feeds all of the affected lights. Check for a common ground if several components that seem unrelated are not functioning correctly.
CIRCUIT TROUBLESHOOTING PROCEDURE Follow these steps when troubleshooting wiring problems. STEP 1
488
Verify the malfunction. If, for example, the backup lights do not operate, make certain that the ignition is on (key on,
CHAPTER 4 5
engine off), with the gear selector in reverse, and check for operation of the backup lights. STEP 2
Check everything else that does or does not operate correctly. For example, if the taillights are also not working, the problem could be a loose or broken ground connection in the trunk area that is shared by both the backup lights and the taillights.
STEP 3
Check the fuse for the backup lights. SEE FIGURE 45–34.
STEP 4
Check for voltage at the backup light socket. This can be done using a test light or a voltmeter.
If voltage is available at the socket, the problem is either a defective bulb or a poor ground at the socket or a ground wire connection to the body or frame. If no voltage is available at the socket, consult a wiring diagram for the type of vehicle being tested. The wiring diagram should show all of the wiring and components
?
FREQUENTLY ASKED QUESTION
Where to Start?
FIGURE 45–34 Always check the simple things first. Check the fuse for the circuit you are testing. Maybe a fault in another circuit controlled by the same fuse could have caused the fuse to blow. Use a test light to check that both sides of the fuse have voltage.
included in the circuit. For example, the backup light current must flow through the fuse and ignition switch to the gear selector switch before traveling to the rear backup light socket. As stated in the second step, the fuse used for the backup lights may also be used for other vehicle circuits. The wiring diagram can be used to determine all other components that share the same fuse. If the fuse is blown (open circuit), the cause can be a short in any of the circuits sharing the same fuse. Because the backup light circuit current must be switched on and off by the gear selector switch, an open in the switch can also prevent the backup lights from functioning.
LOCATING A SHORT CIRCUIT TERMINOLOGY A short circuit usually blows a fuse, and a replacement fuse often also blows in the attempt to locate the source of the short circuit. A short circuit is an electrical connection to another wire or to ground before the current flows through some or all of the resistance in the circuit. A short-to-ground will always blow a fuse and usually involves a wire on the power side of the circuit coming in contact with metal. Therefore, a thorough visual inspection should be performed around areas involving heat or movement, especially if there is evidence of a previous collision or previous repair that may not have been properly completed. A short-to-voltage may or may not cause the fuse to blow and usually affects another circuit. Look for areas of heat or movement where two power wires could come in contact with each other. Several methods can be used to locate the short. FUSE REPLACEMENT METHOD Disconnect one component at a time and then replace the fuse. If the new fuse blows, continue the process until you determine the location of the short. This
The common question is, where does a technician start the troubleshooting when using a wiring diagram (schematic)? HINT 1 If the circuit contains a relay, start your diagnosis at the relay. The entire circuit can be tested at the terminals of the relay. HINT 2 The easiest first step is to locate the unit on the schematic that is not working at all or not working correctly. a. Trace where the unit gets its ground connection. b. Trace where the unit gets its power connection. Often a ground is used by more than one component. Therefore, ensure that everything else is working correctly. If not, then the fault may lie at the common ground (or power) connection. HINT 3 Divide the circuit in half by locating a connector or a part of the circuit that can be accessed easily. Then check for power and ground at this midpoint. This step could save you much time. HINT 4 Use a fused jumper wire to substitute a ground or a power source to replace a suspected switch or section of wire.
method uses many fuses and is not a preferred method for finding a short circuit.
CIRCUIT BREAKER METHOD
Another method is to connect an automotive circuit breaker to the contacts of the fuse holder with alligator clips. Circuit breakers are available that plug directly into the fuse panel, replacing a blade-type fuse. The circuit breaker will alternately open and close the circuit, protecting the wiring from possible overheating damage while still providing current flow through the circuit. NOTE: A heavy-duty (HD) flasher can also be used in place of a circuit breaker to open and close the circuit. Wires and terminals must be made to connect the flasher unit where the fuse normally plugs in. All components included in the defective circuit should be disconnected one at a time until the circuit breaker stops clicking. The unit that was disconnected and stopped the circuit breaker clicking is the unit causing the short circuit. If the circuit breaker continues to click with all circuit components unplugged, the problem is in the wiring from the fuse panel to any one of the units in the circuit. Visual inspection of all the wiring or further disconnecting will be necessary to locate the problem.
TEST LIGHT METHOD To use the test light method, simply remove the blown fuse and connect a test light to the terminals of the fuse holder (polarity does not matter). If there is a short circuit, current will flow from the power side of the fuse holder through the test light and on to ground through the short circuit, and the test light will then light. Unplug the connectors or components protected by the fuse until the test light goes out. The circuit that was disconnected, which caused the test light to go out, is the circuit that is shorted. W I RI N G SC H E MAT I C S AN D C I RC U IT T ES T IN G
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(a)
(b)
FIGURE 45–35 (a) After removing the blown fuse, a pulsing circuit breaker is connected to the terminals of the fuse. (b) The circuit breaker causes current to flow, then stop, then flow again, through the circuit up to the point of the short-to-ground. By observing the Gauss gauge, the location of the short is indicated near where the needle stops moving due to the magnetic field created by the flow of current through the wire.
BUZZER METHOD The buzzer method is similar to the test light method, but uses a buzzer to replace a fuse and act as an electrical load. The buzzer will sound if the circuit is shorted and will stop when the part of the circuit that is grounded is unplugged. OHMMETER METHOD
The fourth method uses an ohmmeter connected to the fuse holder and ground. This is the recommended method of finding a short circuit, as an ohmmeter will indicate low ohms when connected to a short circuit. However, an ohmmeter should never be connected to an operating circuit. The correct procedure for locating a short using an ohmmeter is as follows: 1. Connect one lead of an ohmmeter (set to a low scale) to a good clean metal ground and the other lead to the circuit (load) side of the fuse holder. CAUTION: Connecting the lead to the power side of the fuse holder will cause current flow through and damage to the ohmmeter. 2. The ohmmeter will read zero or almost zero ohms if the circuit or a component in the circuit is shorted. 3. Disconnect one component in the circuit at a time and watch the ohmmeter. If the ohmmeter reading goes to high ohms or infinity, the component just unplugged was the source of the short circuit. 4. If all of the components have been disconnected and the ohmmeter still reads low ohms, then disconnect electrical connectors until the ohmmeter reads high ohms. The location of the short to ground is then between the ohmmeter and the disconnected connector. NOTE: Some meters, such as the Fluke 87, can be set to beep (alert) when the circuit closes or when the circuit opens—a very useful feature.
GAUSS GAUGE METHOD
If a short circuit blows a fuse, a special pulsing circuit breaker (similar to a flasher unit) can be installed in the circuit in place of the fuse. Current will flow through the circuit until the circuit breaker opens the circuit. As soon as the circuit breaker opens the circuit, it closes again. This on-and-off current flow creates a pulsing magnetic field around the wire carrying the current.
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FUSE CIRCUIT BREAKER CAUSING PULSING CURRENT FLOW IN AFFECTED CIRCUIT GAUSS GAUGE OSCILLATING BACK AND FORTH UNTIL GAUGE REACHES POINT OF SHORT CIRCUIT
FIGURE 45–36 A Gauss gauge can be used to determine the location of a short circuit even behind a metal panel.
A Gauss gauge is a handheld meter that responds to weak magnetic fields. It is used to observe this pulsing magnetic field, which is indicated on the gauge as needle movement. This pulsing magnetic field will register on the Gauss gauge even through the metal body of the vehicle. A needle-type compass can also be used to observe the pulsing magnetic field. SEE FIGURES 45–35 AND 45–36.
ELECTRONIC TONE GENERATOR TESTER
An electronic tone generator tester can be used to locate a short-to-ground or an open circuit. Similar to test equipment used to test telephone and cable television lines, a tone generator tester generates a tone that can be heard through a receiver (probe). SEE FIGURE 45–37. The tone will be generated as long as there is a continuous electrical path along the circuit. The signal will stop if there is a shortto-ground or an open in the circuit. SEE FIGURE 45–38. The windings in the solenoids and relays will increase the strength of the signal in these locations.
TECH TIP
ELECTRICAL TROUBLESHOOTING GUIDE
Heat or Movement Electrical shorts are commonly caused either by movement, which causes the insulation around the wiring to be worn away, or by heat melting the insulation. When checking for a short circuit, first check the wiring that is susceptible to heat, movement, and damage. 1. Heat. Wiring near heat sources, such as the exhaust system, cigarette lighter, or alternator 2. Wire movement. Wiring that moves, such as in areas near the doors, trunk, or hood 3. Damage. Wiring subject to mechanical injury, such as in the trunk, where heavy objects can move around and smash or damage wiring; can also occur as a result of an accident or a previous repair
When troubleshooting any electrical component, remember the following hints to find the problem faster and more easily. 1. For a device to work, it must have two things: power and ground. 2. If there is no power to a device, an open power side (blown fuse, etc.) is indicated. 3. If there is power on both sides of a device, an open ground is indicated. 4. If a fuse blows immediately, a grounded power-side wire is indicated. 5. Most electrical faults result from heat or movement.
TECH TIP Wiggle Test
FIGURE 45–37 A tone generator-type tester used to locate open circuits and circuits that are shorted-to-ground. Included with this tester is a transmitter (tone generator), receiver probe, and headphones for use in noisy shops.
Intermittent electrical problems are common yet difficult to locate. To help locate these hard-to-find problems, try operating the circuit and then start wiggling the wires and connections that control the circuit. If in doubt where the wiring goes, try moving all the wiring starting at the battery. Pay particular attention to wiring running near the battery or the windshield washer container. Corrosion can cause wiring to fail, and battery acid fumes and alcohol-based windshield washer fluid can start or contribute to the problem. If you notice any change in the operation of the device being tested while wiggling the wiring, look closer in the area you were wiggling until you locate and correct the actual problem.
LOAD SIDE OF FUSE TERMINAL
RED LEAD BLACK LEAD GOOD CHASSIS GROUND LIGHT SWITCH
LOCATION OF SHORT-TO-GROUND
TONE GENERATOR
VEHICLE BATTERY
FIGURE 45–38 To check for a short-to-ground using a tone generator, connect the black transmitter lead to a good chassis ground and the red lead to the load side of the fuse terminal. Turn the transmitter on and check for tone signal with the receiver. Using a wiring diagram, follow the strongest signal to the location of the short-to-ground. There will be no signal beyond the fault, either a short-to-ground as shown or an open circuit.
W I RI N G SC H E MAT I C S AN D C I R C U IT T ES T IN G
491
6. Most noncomputer-controlled devices operate by opening and closing the power side of the circuit (power-side switch). 7. Most computer-controlled devices operate by opening and closing the ground side of the circuit (ground-side switch).
STEP-BY-STEP TROUBLESHOOTING PROCEDURE Knowing what should be done and when it should be done is a major concern for many technicians trying to repair an electrical problem. The following field-tested procedure provides a step-by-step guide for troubleshooting an electrical fault. Determine the customer concern (complaint) and get as much information as possible from the customer or service advisor. a. When did the problem start? b. Under what conditions does the problem occur? c. Have there been any recent previous repairs to the vehicle which could have created the problem?
FIGURE 45–39 Antistatic spray can be used by customers to prevent being shocked when they touch a metal object like the door handle.
STEP 2
Verify the customer’s concern by actually observing the fault.
STEP 3
Perform a thorough visual inspection and be sure to check everything that does and does not work.
STEP 4
Check for technical service bulletins (TSBs).
STEP 5
Locate the wiring schematic for the circuit being diagnosed.
STEP 6
Check the factory service information and follow the troubleshooting procedure. a. Determine how the circuit works. b. Determine which part of the circuit is good, based on what works and what does not work. c. Isolate the problem area.
A customer complained that after driving for a while, he got a static shock whenever he grabbed the door handle when exiting the vehicle. The customer thought that there must be an electrical fault and that the shock was coming from the vehicle itself. In a way, the shock was caused by the vehicle, but it was not a fault. The service technician sprayed the cloth seats with an antistatic spray and the problem did not reoccur. Obviously, a static charge was being created by the movement of the driver’s clothing on the seats and then discharged when the driver touched the metal door handle. SEE FIGURE 45–39.
STEP 1
NOTE: Split the circuit in half to help isolate the problem and start at the relay (if the circuit has a relay).
REAL WORLD FIX Shocking Experience
STEP 7
Determine the root cause and repair the vehicle.
STEP 8
Verify the repair and complete the work order by listing the three Cs (complaint, cause, and correction).
REVIEW QUESTIONS 1. List the numbers used on schematics to indicate grounds, splices, and connectors and where they are used in the vehicle.
3. List three methods that can be used to help locate a short circuit.
2. List and identify the terminals of a typical ISO type relay.
4. How can a tone generator be used to locate a short circuit?
CHAPTER QUIZ 1. On a wiring diagram, S110 with a “.8 BRN/BLK” means ___________. a. Circuit #.8, spliced under the hood b. A connector with 0.8 mm2 wire c. A splice of a brown with black stripe, wire size being 0.8 mm2 (18 gauge AWG) d. Both a and b
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2. Where is connector C250? a. Under the hood b. Under the dash c. In the passenger compartment d. In the trunk
3. All switches illustrated in schematics are ___________. a. Shown in their normal position b. Always shown in their on position c. Always shown in their off position d. Shown in their on position except for lighting switches 4. When testing a relay using an ohmmeter, which two terminals should be touched to measure the coil resistance? a. 87 and 30 b. 86 and 85 c. 87a and 87 d. 86 and 87 5. Technician A says that a good relay should measure between 60 and 100 ohms across the coil terminals. Technician B says that OL should be displayed on an ohmmeter when touching terminals 30 and 87. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 6. Which relay terminal is the normally closed (N.C.) terminal? a. 30 b. 85 c. 87 d. 87a
chapter
46
7. Technician A says that there is often more than one circuit being protected by each fuse. Technician B says that more than one circuit often shares a single ground connector. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 8. Two technicians are discussing finding a short-to-ground using a test light. Technician A says that the test light, connected in place of the fuse, will light when the circuit that has the short is disconnected. Technician B says that the test light should be connected to the positive (⫹) and negative (⫺) terminals of the battery during this test. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 9. A short circuit can be located using a ___________. a. Test light c. Tone generator b. Gauss gauge d. All of the above 10. For an electrical device to operate, it must have ___________. a. Power and a ground b. A switch and a fuse c. A ground and fusible link d. A relay to transfer the current to the device
CAPACITANCE AND CAPACITORS
OBJECTIVES: After studying Chapter 46, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic Systems). • Explain capacitance. • Describe how a capacitor can be used to filter electrical noise. • Describe how a capacitor can store an electrical charge. • Explain how a capacitor circuit can be used as a timer circuit. KEY TERMS: Capacitance 493 • Condenser 493 • Dielectric 494 • Farads 495 • Leyden jar 493
CAPACITANCE DEFINITION
Capacitance is the ability of an object or surface to store an electrical charge. Around 1745, Ewald Christian von Kliest and Pieter van Musschenbroek independently discovered capacitance in an electric circuit. While engaged in separate studies of electrostatics, they discovered that an electric charge could be stored for a period of time. They used a device, now called a Leyden jar, for their experimentation, which consisted of a glass jar filled with water, with a nail piercing the stopper and dipping into the water. The two scientists connected the nail to an electrostatic charge. After disconnecting the nail from the source of the charge, they felt
a shock by touching the nail, demonstrating that the device had stored the charge. In 1747, John Bevis lined both the inside and outside of the jar with foil. This created a capacitor with two conductors (the inside and outside metal foil layers) equally separated by the insulating glass. SEE FIGURE 46–1. The Leyden jar was also used by Benjamin Franklin to store the charge from lightning as well as in other experiments. The natural phenomenon of lightning includes capacitance, because huge electrical fields develop between cloud layers or between clouds and the earth prior to a lightning strike. NOTE: Capacitors are also called condensers. This term developed because electric charges collect, or condense, on the plates of a capacitor much like water vapor collects and condenses on a cold bottle or glass.
C APAC I T AN C E AN D C A P A C IT ORS
493
PLATES
SPARK
DIELECTRIC
FIGURE 46–2 This simple capacitor, made of two plates separated by an insulating material, is called a dielectric. NEGATIVE PLATE — EXCESS ELECTRONS
BATTERY
FIGURE 46–1 A Leyden jar can be used to store an electrical charge.
MATERIAL
DIELECTRIC CONSTANT
Vacuum
1
Air
1.00059
Polystyrene
2.5
Paper
3.5
Mica
5.4
Flint glass
9.9
Methyl alcohol
35
Glycerin
56.2
Pure water
81
CHART 46–1 The higher the dielectric constant is, the better the insulating properties between the plates of the capacitor.
CAPACITOR CONSTRUCTION AND OPERATION CONSTRUCTION
A capacitor (also called a condenser) consists of two conductive plates with an insulating material between them. The insulating material is commonly called a dielectric. This substance is a poor conductor of electricity and can include air, mica, ceramic, glass, paper, plastic, or any similar nonconductive material. The dielectric constant is the relative strength of a material against the flow of electrical current. The higher the number is, the better the insulating properties. SEE CHART 46–1.
OPERATION When a capacitor is placed in a closed circuit, the voltage source (battery) forces electrons around the circuit. Because electrons cannot flow through the dielectric of the capacitor, excess electrons collect on what becomes the negatively charged plate. At the same time, the other plate loses electrons and, therefore, becomes positively charged. SEE FIGURE 46–2. Current continues until the voltage charge across the capacitor plates becomes the same as the source voltage. At that time, the
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ELECTRON FLOW
CAPACITOR
POSITIVE PLATE — DEFICIENCY OF ELECTRONS
FIGURE 46–3 As the capacitor is charging, the battery forces electrons through the circuit.
12 VOLTS
ELECTROSTATIC FIELD BETWEEN CAPACITOR PLATES
FIGURE 46–4 When the capacitor is charged, there is equal voltage across the capacitor and the battery. An electrostatic field exists between the capacitor plates. No current flows in the circuit.
negative plate of the capacitor and the negative terminal of the battery are at the same negative potential. SEE FIGURE 46–3. The positive plate of the capacitor and the positive terminal of the battery are also at equal positive potentials. There is then a voltage charge across the battery terminals and an equal voltage charge across the capacitor plates. The circuit is in balance, and there is no current. An electrostatic field now exists between the capacitor plates because of their opposite charges. It is this field that stores energy. In other words, a charged capacitor is similar to a charged battery. SEE FIGURE 46–4. If the circuit is opened, the capacitor will hold its charge until it is connected into an external circuit through which it can discharge. When the charged capacitor is connected to an external circuit, it discharges. After discharging, both plates of the capacitor are neutral because all the energy from a circuit stored in a capacitor is returned when it is discharged. SEE FIGURE 46–5. Theoretically, a capacitor holds its charge indefinitely. Actually, the charge slowly leaks off the capacitor through the dielectric. The better the dielectric, the longer the capacitor holds its charge. To avoid an electrical shock, any capacitor should be treated as if it were charged until it is proven to be discharged. To safely discharge a capacitor, use a test light with the clip attached to a good ground, and touch the pigtail or terminal with the point of the test light. SEE FIGURE 46–6 for the symbol for capacitors as used in electrical schematics.
SWITCH 1
CAPACITOR CHARGING
BATTERY SWITCH 2
SWITCH 1
ELECTRON FLOW
SWITCH 2
ELECTRON FLOW
FREQUENTLY ASKED QUESTION
What Are “Points and Condenser”? Points and condenser are used in point-type ignition systems.
Points. A set of points uses one stationary contact and a movable contact that is opened by a cam lobe inside the ignition distributor. When the points are closed, current flows through the primary windings of the ignition coil and creates a strong magnetic field. As the engine rotates, the distributor can open the contact points, which opens the circuit to the coil. The stored magnetic field in the coil collapses and generates a high-voltage arc from the secondary winding of the coil. It is this spark that is sent to the spark plugs that ignites the air-fuel mixture inside the engine.
RESISTOR
BATTERY
?
RESISTOR
CAPACITOR DISCHARGING
FIGURE 46–5 The capacitor is charged through one circuit (top) and discharged through another (bottom).
Condenser. The condenser (capacitor) is attached to the points and the case of the condenser is grounded. When the points start to open, the charge built up in the primary winding of the coil would likely start to arc across the opening points. To prevent the points from arcing and to increase how rapidly the current is turned off, the condenser stores the current temporarily.
FIXED CAPACITORS
Points and condenser were used in vehicles and small gasoline engines until the mid-1970s. SEE FIGURE 46–7.
VARIABLE CAPACITORS
FIGURE 46–6 Capacitor symbols are shown in electrical diagrams. The negative plate is often shown curved.
USES FOR CAPACITORS SPIKE SUPPRESSION
FACTORS OF CAPACITANCE Capacitance is governed by three factors.
The surface area of the plates
The distance between the plates
The dielectric material
The larger the surface area of the plates is, the greater the capacitance, because more electrons collect on a larger plate area than on a small one. The closer the plates are to each other, the greater the capacitance, because a stronger electrostatic field exists between charged bodies that are close together. The insulating qualities of the dielectric material also affect capacitance. The capacitance of a capacitor is higher if the dielectric is a very good insulator.
MEASUREMENT OF CAPACITANCE
Capacitance is measured in farads, which is named after Michael Faraday (1791–1867), an English physicist. The symbol for farads is the letter F. If a charge of 1 coulomb is placed on the plates of a capacitor and the potential difference between them is 1 volt, then the capacitance is defined to be 1 farad, or 1 F. One coulomb is equal to the charge of 6.25 ⫻ 1018 electrons. One farad is an extremely large quantity of capacitance. Microfarads (0.000001 farad), or μF, are more commonly used. The capacitance of a capacitor is proportional to the quantity of charge that can be stored in it for each volt difference in potential.
A capacitor can be used in parallel to a coil to reduce the resulting voltage spike that occurs when the circuit is opened. The energy stored to the magnet field of the coil is rapidly released at this time. The capacitor acts to absorb the high voltage produced and stop it from interfering with other electronic devices, such as automotive radio and video equipment.
NOISE FILTERING
Interference in a sound system or radio is usually due to alternating current (AC) voltage created somewhere in the vehicle, such as in the alternator. A capacitor does the following:
Blocks the flow of direct current (DC)
Allows alternating current (AC) to pass
By connecting a capacitor (condenser) to the power lead of the radio or sound system amplifier, the AC voltage passes through the capacitor to the ground where the other end of the capacitor is connected. Therefore, the capacitor provides a path for the AC without affecting the DC power circuit. SEE FIGURE 46–8. Because a capacitor stores a voltage charge, it opposes or slows any voltage change in a circuit. Therefore, capacitors are often used as voltage “shock absorbers.” You sometimes find a capacitor attached to one terminal of an ignition coil. In this application, the capacitor absorbs and dampens changes in ignition voltage that interfere with radio reception.
SUPPLEMENTAL POWER SOURCE A capacitor can be used to supply electrical power for short bursts in an audio system to help drive the speakers. Woofers and subwoofers require a lot of electrical current that often cannot be delivered by the amplifier itself. SEE FIGURE 46–9. TIMER CIRCUITS
Capacitors are used in electronic circuits as part of a timer, to control window defoggers, interior lighting, pulse
C APAC I T AN C E AN D C A P A C IT ORS
495
CONDENSER
CAM
POINTS
FIGURE 46–7 A point-type distributor shown with the condenser from an old vehicle being tested on a distributor machine. AC INTERFERENCE 12 V FROM THE BATTERY OR ALTERNATOR
AMPLIFIER OR RADIO
CAPACITOR
FIGURE 46–8 A capacitor blocks direct current (DC) but passes alternating current (AC). A capacitor makes a very good noise suppressor because most of the interference is AC and the capacitor will conduct this AC to ground before it can reach the radio or amplifier.
up of several million memory cells. In a DRAM chip, each memory cell consists of a capacitor. When a capacitor is electrically charged, it is said to store the binary digit 1, and when discharged, it represents 0.
CONDENSER MICROPHONES
A microphone converts sound waves into an electric signal. All microphones have a diaphragm that vibrates as sound waves strike. The vibrating diaphragm in turn causes an electrical component to create an output flow of current at a frequency proportional to the sound waves. A condenser microphone uses a capacitor for this purpose. In a condenser microphone, the diaphragm is the negatively charged plate of a charged capacitor. When a sound wave compresses the diaphragm, the diaphragm is moved closer to the positive plate. Decreasing the distance between the plates increases the electrostatic attraction between them, which results in a flow of current to the negative plate. As the diaphragm moves out in response to sound waves, it also moves farther from the positive plate. Increasing the distance between the plates decreases the electrostatic attraction between them. This results in a flow of current back to the positive plate. These alternating flows of current provide weak electronic signals that travel to an amplifier and then to a loudspeaker.
CAPACITORS IN CIRCUITS CAPACITORS IN PARALLEL CIRCUITS FIGURE 46–9 A 1 farad capacitor used to boost the power to large speakers. wipers, and automatic headlights. The capacitors store energy and then are allowed to discharge through a resistance load. The greater the capacity of the capacitor and the higher the resistance load, the longer the time it takes for the capacitor to discharge.
COMPUTER MEMORY
In most cases, the main memory of a computer is a high-speed random-access memory (RAM). One type of main memory, called dynamic random-access memory (DRAM), is the most commonly used type of RAM. A single memory chip is made
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Capacitance can be increased in a circuit by connecting capacitors in parallel. For example, if a greater boost is needed for a sound system, then additional capacitors should be connected in parallel because their value adds together. SEE FIGURE 46–10. We know that capacitance of a capacitor can be increased by increasing the size of its plates. Connecting two or more capacitors in parallel in effect increases plate size. Increasing plate area makes it possible to store more charge and therefore creates greater capacitance. To determine total capacitance of several parallel capacitors, simply add up their individual values. The following is the formula for calculating total capacitance in a circuit containing capacitors in parallel. CT C1 C2 C3 . . .
FIGURE 46–10 Capacitors in parallel effectively increase the capacitance. For example, 220 μF ⫹ 220 μF ⫽ 440 μF when connected in parallel.
CAPACITORS IN SERIES CIRCUITS Capacitance can be decreased in a circuit by capacitors in series, as shown in FIGURE 46–11. We know that capacitance of a capacitor can be decreased by placing the plates farther apart. Connecting two or more capacitors in series in effect increases the distance between the plates and thickness of the dielectric, thereby decreasing the amount of capacitance. Following is the formula for calculating total capacitance in a circuit containing two capacitors in series. C1 3 C2 CT 5 C1 3 C2 For example,
220 mF 3 220 mF 48,400 5 5 110 mF 220 mF 3 220 mF 440
FIGURE 46–11 Capacitors in series decrease the capacitance. NOTE: Capacitors are often used to reduce radio interference or to improve the performance of a high-power sound system. Additional capacitance can, therefore, be added by attaching another capacitor in parallel.
SUPPRESSION CAPACITORS
Capacitors are installed across many circuits and switching points to absorb voltage fluctuations. Among other applications, they are used across the following:
The primary circuit of some electronic ignition modules
The output terminal of most alternators
The armature circuit of some electric motors
Radio choke coils reduce current fluctuations resulting from selfinduction. They are often combined with capacitors to act as electromagnetic interference (EMI) filter circuits for windshield wiper and electric fuel pump motors. Filters also may be incorporated in wiring connectors.
REVIEW QUESTIONS 1. How does a capacitor store an electrical charge?
3. Where can a capacitor be used as a power source?
2. How should two capacitors be electrically connected if greater capacitance is needed?
4. How can a capacitor be used as a noise filter?
CHAPTER QUIZ 1. A capacitor ______________. a. Stores electrons c. Blocks DC b. Passes AC d. All of the above 2. A capacitor can also be called a ______________. a. Condenser c. Farad b. Dielectric d. DRAM 3. Capacitors are commonly used as a ______________. a. Voltage supply c. Noise filter b. Timer d. All of the above 4. A charged capacitor acts like a ______________. a. Switch c. Resistor b. Battery d. Coil 5. The unit of measurement for capacitor rating is the ____________. a. Ohm c. Farad b. Volt d. Ampere 6. Two technicians are discussing the operation of a capacitor. Technician A says that a capacitor can create electricity. Technician B says that a capacitor can store electricity. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
7. Capacitors block the flow of ______________ current but allow ______________ current to pass. a. Strong; weak b. AC; DC c. DC; AC d. Weak; strong 8. To increase the capacity, what could be done? a. Connect another capacitor in series. b. Connect another capacitor in parallel. c. Add a resistor between two capacitors. d. Both a and b 9. A capacitor can be used in what components? a. Microphone b. Radio c. Speaker d. All of the above 10. A capacitor used for spike protection will normally be placed in ______________ to the load or circuit. a. Series b. Parallel c. Either series or parallel d. Parallel with a resistor in series C APAC I T AN C E AN D C A P A C IT ORS
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chapter
47
MAGNETISM AND ELECTROMAGNETISM
OBJECTIVES: After studying Chapter 47, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic Systems). • Explain magnetism. • Describe how magnetism and voltage are related. • Describe how an ignition coil works. • Explain how an electromagnet works. KEY TERMS: Ampere-turns 502 • Counter electromotive force (CEMF) 504 • Electromagnet 502 • Electromagnetic induction 504 • Electromagnetic interference (EMI) 506 • Electromagnetism 500 • Flux density 499 • Flux lines 498 • Ignition control module (ICM) 505 • Left-hand rule 500 • Lenz’s law 504 • Magnetic flux 498 • Magnetic induction 499 • Magnetism 498 • Mutual induction 504 • Permeability 499 • Pole 498 • Relay 502 • Reluctance 500 • Residual magnetism 499 • Right-hand rule 500 • Turns ratio 505
FUNDAMENTALS OF MAGNETISM
N
DEFINITION
Magnetism is a form of energy that is caused by the motion of electrons in some materials. It is recognized by the attraction it exerts on other materials. Like electricity, magnetism cannot be seen. It can be explained in theory, however, because it is possible to see the results of magnetism and recognize the actions that it causes. Magnetite is the most naturally occurring magnet. Naturally magnetized pieces of magnetite, called lodestone, will attract and hold small pieces of iron. SEE FIGURE 47–1. Many other materials can be artificially magnetized to some degree, depending on their atomic structure. Soft iron is very easy to magnetize, whereas some materials, such as aluminum, glass, wood, and plastic, cannot be magnetized at all.
LINES OF FORCE The lines that create a field of force around a magnet are believed to be caused by the way groups of atoms are aligned in the magnetic material. In a bar magnet, the lines are concentrated at both ends of the bar and form closed, parallel loops in three dimensions around the magnet. Force does not flow along
TECH TIP
FIGURE 47–1 A freely suspended natural magnet (lodestone) will point toward the magnetic north pole.
N
N
S
S
N
S
FIGURE 47–2 If a magnet breaks or is cracked, it becomes two weaker magnets.
A Cracked Magnet Becomes Two Magnets Magnets are commonly used in vehicle crankshaft, camshaft, and wheel speed sensors. If a magnet is struck and cracks or breaks, the result is two smaller-strength magnets. Because the strength of the magnetic field is reduced, the sensor output voltage is also reduced. A typical problem occurs when a magnetic crankshaft sensor becomes cracked, resulting in a no-start condition. Sometimes the cracked sensor works well enough to start an engine that is cranking at normal speeds but will not work when the engine is cold. SEE FIGURE 47–2.
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these lines the way electrical current flows, but the lines do have direction. They come out of the north end, or pole, of the magnet and enter at the other end. SEE FIGURE 47–3. The opposite ends of a magnet are called its north and south poles. In reality, they should be called the “north seeking” and “south seeking” poles, because they seek the earth’s North Pole and South Pole, respectively. The more lines of force that are present, the stronger the magnet becomes. The magnetic lines of force, also called magnetic flux or flux lines, form a magnetic field. The terms magnetic field, lines of force, flux, and flux lines are used interchangeably.
N
S
N
S
UNLIKE POLES ATTRACT
N
S
S
N
LIKE POLES REPEL
N
FIGURE 47–5 Magnetic poles behave like electrically charged particles—unlike poles attract and like poles repel.
S
TECH TIP Magnetize a Steel Needle
FIGURE 47–3 Magnetic lines of force leave the north pole and return to the south pole of a bar magnet.
A piece of steel can be magnetized by rubbing a magnet in one direction along the steel. This causes the atoms to line up in the steel, so it acts like a magnet. The steel often will not remain magnetized, whereas the true magnet is permanently magnetized. When soft iron or steel is used, such as a paper clip, it will lose its magnetism quickly. The atoms in a magnetized needle can be disturbed by heating it or by dropping the needle on a hard object, which would cause the needle to lose its magnetism. Soft iron is used inside ignition coils because it will not keep its magnetism.
ATTRACTING OR REPELLING
FIGURE 47–4 Iron filings and a compass can be used to observe the magnetic lines of force.
Flux density refers to the number of flux lines per unit of area. A magnetic field can be measured using a Gauss gauge, named for German scientist Johann Carl Friedrick Gauss (1777–1855). Magnetic lines of force can be seen by spreading fine iron filings or dust on a piece of paper laid on top of a magnet. A magnetic field can also be observed by using a compass. A compass is simply a thin magnet or magnetized iron needle balanced on a pivot. The needle will rotate to point toward the opposite pole of a magnet. The needle can be very sensitive to small magnetic fields. Because it is a small magnet, a compass usually has one north end (marked N) and one south end (marked S). SEE FIGURE 47–4.
MAGNETIC INDUCTION
If a piece of iron or steel is placed in a magnetic field, it will also become magnetized. This process of creating a magnet by using a magnetic field is called magnetic induction. If the metal is then removed from the magnetic field, and it retains some magnetism, this is called residual magnetism.
The poles of a magnet are called north (N) and south (S) because, when a magnet is suspended freely, the poles tend to point toward the earth’s North Pole and South Pole. Magnetic flux lines exit from the north pole and bend around to enter the south pole. An equal number of lines exit and enter, so magnetic force is equal at both poles of a magnet. Flux lines are concentrated at the poles, and therefore magnetic force (flux density) is stronger at the ends. Magnetic poles behave like positively and negatively charged particles. When unlike poles are placed close together, the lines exit from one magnet and enter the other. The two magnets are pulled together by flux lines. If like poles are placed close together, the curving flux lines meet head on, forcing the magnets apart. Therefore, like poles of a magnet repel and unlike poles attract. SEE FIGURE 47–5.
PERMEABILITY Magnetic flux lines cannot be insulated. There is no known material through which magnetic force does not pass, if the force is strong enough. However, some materials allow the force to pass through more easily than others. This degree of passage is called permeability. Iron allows magnetic flux lines to pass through much more easily than air, so iron is highly permeable. An example of this characteristic is the use of a reluctor wheel in magnetic-type camshaft position (CMP) and crankshaft position (CKP) sensors. The teeth on a reluctor cause the magnetic field to increase as each tooth gets closer to the sensor and decrease as the tooth moves away, thus creating an AC voltage signal. SEE FIGURE 47–6. RELUCTANCE Although there is no absolute insulation for magnetism, certain materials resist the passage of magnetic force. This can be compared to resistance without an electrical circuit. Air does
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FIGURE 47–6 A crankshaft position sensor and reluctor (notched wheel).
not allow easy passage, so air has a high reluctance. Magnetic flux lines tend to concentrate in permeable materials and avoid materials with high reluctance. As with electricity, magnetic force follows the path of least resistance.
ELECTROMAGNETISM DEFINITION Scientists did not discover that current-carrying conductors also are surrounded by a magnetic field until 1820. These fields may be made many times stronger than those surrounding conventional magnets. Also, the magnetic field strength around a conductor may be controlled by changing the current.
As current increases, more flux lines are created and the magnetic field expands.
As current decreases, the magnetic field contracts. The magnetic field collapses when the current is shut off.
The interaction and relationship between magnetism and electricity is known as electromagnetism.
CREATING AN ELECTROMAGNET
An easy way to create an electromagnet is to wrap a nail with 20 turns of insulated wire and connect the ends to the terminals of a 1.5 volt dry cell battery. When energized, the nail will become a magnet and will be able to pick up tacks or other small steel objects.
STRAIGHT CONDUCTOR
The magnetic field surrounding a straight, current-carrying conductor consists of several concentric cylinders of flux that are the length of the wire. The amount of current flow (amperes) determines how many flux lines (cylinders) there will be and how far out they extend from the surface of the wire. SEE FIGURE 47–7.
LEFT-HAND AND RIGHT-HAND RULES
Magnetic flux cylinders have direction, just as the flux lines surrounding a bar magnet have direction. The left-hand rule is a simple way to determine this
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TECH TIP Electricity and Magnetism Electricity and magnetism are closely related because any electrical current flowing through a conductor creates a magnetic field. Any conductor moving through a magnetic field creates an electrical current. This relationship can be summarized as follows: • Electricity creates magnetism. • Magnetism creates electricity. From a service technician’s point of view, this relationship is important because wires carrying current should always be routed as the factory intended to avoid causing interference with another circuit or electronic component. This is especially important when installing or servicing spark plug wires, which carry high voltages and can cause high electromagnetic interference.
direction. When you grasp a conductor with your left hand so that your thumb points in the direction of electron flow (⫺ to ⫹) through the conductor, your fingers curl around the wire in the direction of the magnetic flux lines. SEE FIGURE 47–8. Most automotive circuits use the conventional theory of current (⫺ to ⫹) and, therefore, the right-hand rule is used to determine the direction of the magnetic flux lines. SEE FIGURE 47–9.
FIELD INTERACTION
The cylinders of flux surrounding current-carrying conductors interact with other magnetic fields. In the following illustrations, the cross symbol (⫹) indicates current moving inward, or away from you. It represents the tail of an arrow. The dot symbol (•) represents an arrowhead and indicates current moving outward. If two conductors carry current in opposite directions, their magnetic fields also carry current in opposite directions
FIGURE 47–10 Conductors with opposing magnetic fields will move apart into weaker fields.
FIGURE 47–7 A magnetic field surrounds a straight, currentcarrying conductor.
MAGNETIC FIELD
CURRENT FLOW
FIGURE 47–8 The left-hand rule for magnetic field direction is used with the electron flow theory.
FIGURE 47–11 Electric motors use the interaction of magnetic fields to produce mechanical energy.
CURRENT FLOW
N
S MAGNETIC FIELD
FIGURE 47–9 The right-hand rule for magnetic field direction is used with the conventional theory of electron flow.
FIGURE 47–12 The magnetic lines of flux surrounding a coil look similar to those surrounding a bar magnet.
(according to the left-hand rule). If they are placed side by side, then the opposing flux lines between the conductors create a strong magnetic field. Current-carrying conductors tend to move out of a strong field into a weak field, so the conductors move away from each other. SEE FIGURE 47–10. If the two conductors carry current in the same direction, then their fields are in the same direction. The flux lines between the two conductors cancel each other out, leaving a very weak field between them. The conductors are drawn into this weak field, and they tend to move toward each other.
NORT
MOTOR PRINCIPLE
Electric motors, such as vehicle starter motors, use this magnetic field interaction to convert electrical energy into mechanical energy. If two conductors carrying current in opposite directions are placed between strong north and south poles, the magnetic field of the conductor interacts with the magnetic fields of the poles. The counterclockwise field of the top conductor adds to the fields of the poles and creates a strong field beneath the conductor. The conductor then tries to move up to get out of this strong field. The clockwise field of the lower conductor adds to the field of the poles and creates a strong field above the conductor. The conductor then tries to move down to get out of this strong field. These forces cause the center of the motor, where the conductors are mounted, to turn clockwise. SEE FIGURE 47–11.
COIL CONDUCTOR
If several loops of wire are made into a coil, then the magnetic flux density is strengthened. Flux lines around a coil are the same as the flux lines around a bar magnet. SEE FIGURE 47–12.
H
FIGURE 47–13 The left-hand rule for coils is shown. They exit from the north pole and enter at the south pole. Use the left-hand rule to determine the north pole of a coil, as shown in FIGURE 47–13. Grasp the coil with your left hand so that your fingers point in the direction of electron flow; your thumb will point toward the north pole of the coil.
ELECTROMAGNETIC STRENGTH The magnetic field surrounding a current-carrying conductor can be strengthened (increased) three ways.
Place a soft iron core in the center of the coil.
Increase the number of turns of wire in the coil.
Increase the current flow through the coil windings.
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RELAY
MOVABLE ARM CONTACT POINTS
COIL
S
N
SWITCH LOAD
N
S
BATTERY
FIGURE 47–14 An iron core concentrates the magnetic lines of force surrounding a coil. FIGURE 47–15 An electromagnetic switch that has a movable arm is referred to as a relay.
Relay
CONSTRUCTION
AMPERAGE RATING
USES
CALLED IN SERVICE INFORMATION
Uses a movable arm
1 to 30 A
Lower current switching, lower cost, more commonly used
Electromagnetic switch or relay
30 to 400 A
Higher cost, used in starter motor circuits and other high-amperage applications
Solenoid, relay, or electromagnetic switch
Coil: 60 to 100 ohms requiring 0.12 to 0.20 A to energize Solenoid
Uses a movable core Coil(s): 0.2 to 0.6 ohm requiring 20 to 60 A to energize
CHART 47–1 Comparison between a relay and a solenoid. Because soft iron is highly permeable, magnetic flux lines pass through it easily. If a piece of soft iron is placed inside a coiled conductor, the flux lines concentrate in the iron core, rather than pass through the air, which is less permeable. The concentration of force greatly increases the strength of the magnetic field inside the coil. Increasing the number of turns in a coil and/or increasing the current flow through the coil results in greater field strength and is proportional to the number of turns. The magnetic field strength is often expressed in the units called ampere-turns. Coils with an iron core are called electromagnets. SEE FIGURE 47–14.
USES OF ELECTROMAGNETISM RELAYS
As mentioned in the previous chapter, a relay is a control device that allows a small amount of current to control a large amount of current in another circuit. A simple relay contains an electromagnetic coil in series with a battery and a switch. Near the electromagnet is a movable flat arm, called an armature, of some material that is attracted by a magnetic field. SEE FIGURE 47–15. The armature pivots at one end and is held a small distance away from the electromagnet by a spring (or by the spring steel of
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?
FREQUENTLY ASKED QUESTION
Solenoid or Relay? Often, either term is used to describe the same part in service information. SEE CHART 47–1 for a summary of the differences.
the movable arm itself). A contact point, made of a good conductor, is attached to the free end of the armature. Another contact point is fixed a small distance away. The two contact points are wired in series with an electrical load and the battery. When the switch is closed, the following occurs. 1. Current travels from the battery through a coil, creating an electromagnet. 2. The magnetic field created by the current attracts the armature, pulling it down until the contact points close. 3. Closing the contacts allows current in the heavy current circuit from the battery to the load. When the switch is open, the following occurs. 1. The electromagnet loses its magnetism when the current is shut off.
HEAT SHIELD
SOLENOID “S” (START) TERMINAL
STARTER MOTOR
“B” (BATTERY) TERMINAL “M” (MOTOR) TERMINAL
(a) NORMALLY CLOSED (N.C.) CONTACT NORMALLY OPEN MOVABLE ARM (N.O.) CONTACT
COIL (60 TO 100 OHMS)
(b) FIGURE 47–16 (a) A starter with attached solenoid. All of the current needed by the starter flows through the two large terminals of the solenoid and through the solenoid contacts inside. (b) A relay is designed to carry lower current compared to a solenoid and uses a movable arm.
2. Spring pressure lifts the arm back up. 3. The heavy current circuit is broken by the opening of the contact points. Relays also may be designed with normally closed contacts that open when current passes through the electromagnetic coil.
SOLENOID A solenoid is an example of an electromagnetic switch. A solenoid uses a movable core rather than a movable arm and is generally used in higher-amperage applications. A solenoid can be a separate unit or attached to a starter such as a starter solenoid. SEE FIGURE 47–16.
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MAGNETIC FLUX LINES
FLUX LINES
CONDUCTOR MOVEMENT
VOLTAGE INDUCED CONDUCTOR
CONDUCTOR
FIGURE 47–17 Voltage can be induced by the relative motion between a conductor and magnetic lines of force.
ELECTROMAGNETIC INDUCTION PRINCIPLES INVOLVED
Electricity can be produced by using the relative movement of an electrical conductor and a magnetic field. There are three items necessary to produce electricity (voltage) from magnetism.
FIGURE 47–18 Maximum voltage is induced when conductors cut across the magnetic lines of force (flux lines) at a 90-degree angle.
Maximum voltage is induced if the conductors break flux lines at 90 degrees. Induced voltage varies proportionately at angles between 0 and 90 degrees. SEE FIGURE 47–18. Voltage can be electromagnetically induced and can be measured. Induced voltage creates current. The direction of induced voltage (and the direction in which current moves) is called polarity and depends upon the direction of the flux lines, as well as the direction of relative motion.
LENZ’S LAW
An induced current moves so that its magnetic field opposes the motion that induced the current. This principle is called Lenz’s law. The relative motion of a conductor and a magnetic field is opposed by the magnetic field of the current it has induced.
1. Electrical conductor (usually a coil of wire) 2. Magnetic field 3. Movement of either the conductor or the magnetic field Therefore:
Electricity creates magnetism.
Magnetism can create electricity.
Magnetic flux lines create an electromotive force, or voltage, in a conductor if either the flux lines or the conductor is moving. This movement is called relative motion. This process is called induction, and the resulting electromotive force is called induced voltage. This creation of a voltage (electricity) in a conductor by a moving magnetic field is called electromagnetic induction. SEE FIGURE 47–17.
VOLTAGE INTENSITY Voltage is induced when a conductor cuts across magnetic flux lines. The amount of the voltage depends on the rate at which the flux lines are broken. The more flux lines that are broken per unit of time, the greater the induced voltage. If a single conductor breaks 1 million flux lines per second, 1 volt is induced. There are four ways to increase induced voltage.
Increase the strength of the magnetic field, so there are more flux lines.
Increase the number of conductors that are breaking the flux lines.
Increase the speed of the relative motion between the conductor and the flux lines so that more lines are broken per time unit.
Increase the angle between the flux lines and the conductor to a maximum of 90 degrees. There is no voltage induced if the conductors move parallel to, and do not break, any flux lines.
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SELF-INDUCTION When current begins to flow in a coil, the flux lines expand as the magnetic field forms and strengthens. As current increases, the flux lines continue to expand, cutting across the wires of the coil and actually inducing another voltage within the same coil. Following Lenz’s law, this self-induced voltage tends to oppose the current that produces it. If the current continues to increase, the second voltage opposes the increase. When the current stabilizes, the countervoltage is no longer induced because there are no more expanding flux lines (no relative motion). When current to the coil is shut off, the collapsing magnetic flux lines self-induce a voltage in the coil that tries to maintain the original current. The self-induced voltage opposes and slows the decrease in the original current. The self-induced voltage that opposes changes in current flow is an inductor called counter electromotive force (CEMF). MUTUAL INDUCTION When two coils are close together, energy may be transferred from one to the other by magnetic coupling called mutual induction. Mutual induction means that the expansion or collapse of the magnetic field around one coil induces a voltage in the second coil.
IGNITION COILS IGNITION COIL WINDINGS Ignition coils use two windings and are wound on the same iron core.
One coil winding is connected to a battery through a switch and is called the primary winding.
The other coil winding is connected to an external circuit and is called the secondary winding.
B
A
MAGNETIC FIELD BUILDING UP
NO MAGNETIC FIELD NO VOLTAGE IN SECONDARY
VOLTAGE INDUCED IN SECONDARY SWITCH CLOSED CURRENT BUILDING UP
SWITCH OPEN NO CURRENT FLOWING C
D
MAGNETIC FIELD MAXIMUM STRENGTH AND CONSTANT
MAGNETIC FIELD COLLAPSING
NO VOLTAGE IN SECONDARY SWITCH CLOSED CURRENT FLOW CONSTANT
VOLTAGE INDUCED IN SECONDARY SWITCH OPEN CURRENT FLOW STOPS
FIGURE 47–19 Mutual induction occurs when the expansion or collapse of a magnetic field around one coil induces a voltage in a second coil.
When the switch is open, there is no current in the primary winding. There is no magnetic field and, therefore, no voltage in the secondary winding. When the switch is closed, current is introduced and a magnetic field builds up around both windings. The primary winding thus changes electrical energy from the battery into magnetic energy of the expanding field. As the field expands, it cuts across the secondary winding and induces a voltage in it. A meter connected to the secondary circuit shows current. SEE FIGURE 47–19. When the magnetic field has expanded to its full strength, it remains steady as long as the same amount of current exists. The flux lines have stopped their cutting action. There is no relative motion and no voltage in the secondary winding, as shown on the meter. When the switch is opened, primary current stops and the field collapses. As it does, flux lines cut across the secondary winding but in the opposite direction. This induces a secondary voltage with current in the opposite direction, as shown on the meter. Mutual induction is used in ignition coils. In an ignition coil, low-voltage primary current induces a very high secondary voltage because of the different number of turns in the primary and secondary windings. Because the voltage is increased, an ignition coil is also called a step-up transformer.
the laminated core are approximately 20,000 turns of fine wire (approximately 42 gauge). These windings are called the secondary coil windings. Surrounding the secondary windings are approximately 150 turns of heavy wire (approximately 21 gauge). These windings are called the primary coil windings. The secondary winding has about 100 times the number of turns of the primary winding, referred to as the turns ratio (approximately 100:1). In many coils, these windings are surrounded with a thin metal shield and insulating paper, and placed into a metal container. The metal container and shield help retain the magnetic field produced in the coil windings. The primary and secondary windings produce heat because of the electrical resistance in the turns of wire. Many coils contain oil to help cool the ignition coil. Other coil designs include the following:
Electrically connected windings. Many ignition coils contain two separate but electrically connected windings of copper wire. This type of coil is called a “married” type and is used in older distributor-type ignition systems and in many coil-on-plug (COP) designs.
Electrically insulated windings. Other coils are true transformers in which the primary and secondary windings are not electrically connected. This type of coil is often called a “divorced” type and is used in all waste-spark-type ignition systems.
IGNITION COIL OPERATION The negative terminal is attached to an ignition control module (ICM, or igniter), which opens and closes the primary ignition circuit by opening or closing the ground return path of the circuit. When the ignition switch is on, voltage should be available at both the positive terminal and the negative terminal of the coil if the primary windings of the coil have continuity. A spark is created by the following sequence of events.
The center of an ignition coil contains a core of laminated soft iron (thin strips of soft iron). This core increases the magnetic strength of the coil. Surrounding
Spool design. Used mostly for coil-on plug design, the coil windings are wrapped around a nylon or plastic spool or bobbin. SEE FIGURE 47–22 on page 507.
A magnetic field is created in the primary winding of the coil when there is 12 volts applied to the primary coil winding and the ignition control module grounds the other end on the coil.
When the ignition control module (or powertrain control module) opens the ground circuit, the stored magnetic field collapses and creates a high voltage (up to 40,000 volts or more) in the secondary winding.
SEE FIGURE 47–20.
IGNITION COIL CONSTRUCTION
Air-cooled, epoxy-sealed E coil. The E coil is so named because the laminated, soft iron core is E shaped, with the coil wire turns wrapped around the center “finger” of the E and the primary winding wrapped inside the secondary winding. SEE FIGURE 47–21 on page 507.
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BATTERY (B+) IGN. SW.
COIL
SECONDARY
PRIMARY
IGNITION MODULE
SPARK PLUG
BATTERY (B+) IGN. SW.
COIL
OR
SECONDARY
PRIMARY
SPARK PLUG IGNITION MODULE
SPARK PLUG
FIGURE 47–20 Some ignition coils are electrically connected, called married (top figure) whereas others use separated primary and secondary windings, called divorced (lower figure).
The high-voltage pulse then flows to the spark plug and creates a spark at the ground electrode inside the engine that ignites the air-fuel mixture inside the cylinder.
ELECTROMAGNETIC INTERFERENCE DEFINITION Until the advent of the onboard computer, electromagnetic interference (EMI) was not a source of real concern to automotive engineers. The problem was mainly one of radio-frequency interference (RFI), caused primarily by the use of secondary ignition cables. Using spark plug wires that contained a high-resistance, nonmetallic core made of carbon, linen, or fiberglass strands impregnated with graphite mostly solved RFI from the secondary ignition system. RFI is a part of electromagnetic interference, which deals with interference that affects radio reception. All electronic devices used in vehicles are affected by EMI/RFI.
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HOW EMI IS CREATED
Whenever there is current in a conductor, an electromagnetic field is created. When current stops and starts, as in a spark plug cable or a switch that opens and closes, the field strength changes. Each time this happens, it creates an electromagnetic signal wave. If it happens rapidly enough, the resulting high-frequency signal waves, or EMI, interfere with radio and television transmission or with other electronic systems such as those under the hood. This is an undesirable side effect of the phenomenon of electromagnetism. Static electric charges caused by friction of the tires with the road, or the friction of engine drive belts contacting their pulleys, also produce EMI. Drive axles, driveshafts, and clutch or brake lining surfaces are other sources of static electric charges. There are four ways of transmitting EMI, all of which can be found in a vehicle.
Conductive coupling is actual physical contact through circuit conductors.
Capacitive coupling is the transfer of energy from one circuit to another through an electrostatic field between two conductors.
FIGURE 47–21 A GM waste-spark ignition coil showing the section of laminations that is shaped like the letter E. These mild steel laminations improve the efficiency of the coil.
FIGURE 47–22 The coil-on-plug (COP) design typically uses a bobbin-type coil.
Resistance suppression. Adding resistance to a circuit to suppress RFI works only for high-voltage systems. This has been done by the use of resistance spark plug cables, resistor spark plugs, and the silicone grease used on the distributor cap and rotor of some electronic ignitions.
Suppression capacitors and coils. Capacitors are installed across many circuits and switching points to absorb voltage fluctuations. Among other applications, they are used across the following:
TECH TIP Cell Phone Interference A cellular phone emits a weak signal if it is turned on, even though it is not being used. This signal is picked up and tracked by cell phone towers. When the cell phone is called, it emits a stronger signal to notify the tower that it is on and capable of receiving a phone call. It is this “handshake” signal that can cause interference in the vehicle. Often this signal causes some static in the radio speakers even though the radio is off, but it can also cause a false antilock brake (ABS) trouble code to set. These signals from the cell phone create a voltage that is induced in the wires of the vehicle. Because the cell phone usually leaves with the customer, the service technician is often unable to verify the customer concern. Remember, the interference occurs right before the cell phone rings. To fix the problem, connect an external antenna to the cell phone. This step will prevent the induction of a voltage in the wiring of the vehicle.
Inductive coupling is the transfer of energy from one circuit to another as the magnetic fields between two conductors form and collapse.
Electromagnetic radiation is the transfer of energy by the use of radio waves from one circuit or component to another.
EMI SUPPRESSION DEVICES which EMI is reduced.
There are four general ways in
The primary circuit of some electronic ignition modules
The output terminal of most alternators
The armature circuit of some electric motors
Coils reduce current fluctuations resulting from selfinduction. They are often combined with capacitors to act as EMI filter circuits for windshield wiper and electric fuel pump motors. Filters also may be incorporated in wiring connectors.
Shielding. The circuits of onboard computers are protected to some degree from external electromagnetic waves by their metal housings.
Ground wires or straps. Ground wires or braided straps between the engine and chassis of an automobile help suppress EMI conduction and radiation by providing a lowresistance circuit ground path. Such suppression ground straps are often installed between rubber-mounted components and body parts. On some models, ground straps are installed between body parts, such as between the hood and a fender panel, where no electrical circuit exists. The strap has no other job than to suppress EMI. Without it, the sheet-metal body and hood could function as a large capacitor. The space between the fender and hood could form an electrostatic field and couple with the computer circuits in the wiring harness routed near the fender panel. SEE FIGURE 47–23.
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FIGURE 47–23 To help prevent underhood electromagnetic devices from interfering with the antenna input, it is important that all ground wires, including the one from this power antenna, be properly grounded.
REVIEW QUESTIONS 1. What is the relationship between electricity and magnetism?
3. What is the result if a magnet cracks?
2. What is the difference between mutual induction and selfinduction?
4. How can EMI be reduced or controlled?
CHAPTER QUIZ 1. Technician A says that magnetic lines of force can be seen by placing iron filings on a piece of paper and then holding them over a magnet. Technician B says that the effects of magnetic lines of force can be seen using a compass. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 2. Unlike magnetic poles ______________, and like magnetic poles ______________. a. Repel; attract c. Repel; repel b. Attract; repel d. Attract; attract 3. The conventional theory for current flow is being used to determine the direction of magnetic lines of force. Technician A says that the left-hand rule should be used. Technician B says that the right-hand rule should be used. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 4. Technician A says that a relay is an electromagnetic switch. Technician B says that a solenoid uses a movable core. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 5. Two technicians are discussing electromagnetic induction. Technician A says that the induced voltage can be increased if the speed is increased between the conductor and the magnetic lines of force. Technician B says that the induced voltage can be increased by increasing the strength of the magnetic field. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
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6. An ignition coil operates using the principle(s) of ______________. a. Electromagnetic induction b. Self-induction c. Mutual induction d. All of the above 7. Electromagnetic interference can be reduced by using a ______________. a. Resistance b. Capacitor c. Coil d. All of the above 8. An ignition coil is an example of a ______________. a. Solenoid b. Step-down transformer c. Step-up transformer d. Relay 9. Magnetic field strength is measured in ______________. a. Ampere-turns b. Flux c. Density d. Coil strength 10. Two technicians are discussing ignition coils. Technician A says that some ignition coils have the primary and secondary windings electrically connected. Technician B says that some coils have totally separate primary and secondary windings that are not electrically connected. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
chapter
48
ELECTRONIC FUNDAMENTALS
OBJECTIVES: After studying Chapter 48, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic Systems Diagnosis). • Identify semiconductor components. • Explain precautions necessary when working with semiconductor circuits. • Discuss where various electronic and semiconductor devices are used in vehicles. • Explain how diodes and transistors work. • Describe how to test diodes and transistors. • List the precautions that a service technician should follow to avoid damage to electronic components from electrostatic discharge. KEY TERMS: Anode 510 • Base 516 • Bipolar transistor 516 • Burn in 511 • Cathode 510 • CHMSL 515 • Clamping diode 512 • Collector 516 • Control current 517 • Darlington pair 517 • Despiking diode 512 • Diode 510 • Doping 509 • Dual inline pins (DIP) 518 • Emitter 516 • ESD 523 • FET 517 • Forward bias 511 • Gate 518 • Germanium 509 • Heat sink 518 • Holes 510 • Hole theory 510 • Impurities 509 • Integrated circuit (IC) 518 • Inverter 522 • Junction 510 • Light emitting diode (LED) 513 • MOSFET 517 • NPN transistor 516 • NTC 515 • N-type material 509 • Op-amps 519 • Photodiodes 514 • Photons 514 • Photoresistor 514 • Phototransistor 518 • Peak inverse voltage (PIV) 513 • Peak reverse voltage (PRV) 513 • PNP transistor 516 • P-type material 510 • PWM 520 • Rectifier bridge 515 • Reverse bias 511 • SCR 515 • Semiconductors 509 • Silicon 509 • Spike protection resistor 513 • Suppression diode 512 • Thermistor 515 • Threshold voltage 517 • Transistor 516 • Zener diode 511
Electronic components are the heart of computers. Knowing how electronic components work helps take the mystery out of automotive electronics.
Si Si Si Si
SEMICONDUCTORS
P Si Si
DEFINITION
Semiconductors are neither conductors nor insulators. The flow of electrical current is caused by the movement of electrons in materials, known as conductors having fewer than four electrons in their atom’s outer orbit. Insulators contain more than four electrons in their outer orbit and cannot conduct electricity because their atomic structure is stable (no free electrons). Semiconductors are materials that contain exactly four electrons in the outer orbit of their atom structure and are, therefore, neither good conductors nor good insulators.
EXAMPLES OF SEMICONDUCTORS
Two examples of semiconductor materials are germanium and silicon, which have exactly four electrons in their valance ring and no free electrons to provide current flow. However, both of these semiconductor materials can be made to conduct current if another material is added to provide the necessary conditions for electron movement.
CONSTRUCTION When another material is added to a semiconductor material in very small amounts, it is called doping. The doping elements are called impurities; therefore, after their addition, the germanium and silicon are no longer considered pure elements. The material added to pure silicon or germanium to make it electrically conductive represents only one atom of impurity for every 100 million atoms of the pure semiconductor material. The resulting
EXCESS (FREE) ELECTRON
FIGURE 48–1 N-type material. Silicon (Si) doped with a material (such as phosphorus) with five electrons in the outer orbit results in an extra free electron. atoms are still electrically neutral, because the number of electrons still equals the number of protons of the combined materials. These combined materials are classified into two groups depending on the number of electrons in the bonding between the two materials.
N-type materials
P-type materials
N-TYPE MATERIAL
N-type material is silicon or germanium that is doped with an element such as phosphorus, arsenic, or antimony, each having five electrons in its outer orbit. These five electrons are combined with the four electrons of the silicon or germanium to total nine electrons. There is room for only eight electrons in the bonding between the semiconductor material and the doping material. This leaves extra electrons, and even though the material is still electrically neutral, these extra electrons tend to repel other electrons outside the material. SEE FIGURE 48–1.
E L E C T RO N I C F U N D A M EN T A L S
509
Si HOLES
P
FREE ELECTRONS
N
Si
Si
NEGATIVE CHARGES
JUNCTION
B Si
Si
HOLE
FIGURE 48–2 P-type material. Silicon (Si) doped with a material, such as boron (B), with three electrons in the outer orbit results in a hole capable of attracting an electron.
POSITIVE CHARGES
FIGURE 48–3 Unlike charges attract and the current carriers (electrons and holes) move toward the junction.
P-TYPE MATERIAL P-type material is produced by doping silicon or germanium with the element boron or the element indium. These impurities have only three electrons in their outer shell and, when combined with the semiconductor material, result in a material with seven electrons, one electron less than is required for atom bonding. This lack of one electron makes the material able to attract electrons, even though the material still has a neutral charge. This material tends to attract electrons to fill the holes for the missing eighth electron in the bonding of the materials. SEE FIGURE 48–2.
JUNCTION
() ANODE
CATHODE () N
P
DIODE
SUMMARY OF SEMICONDUCTORS The following is a summary of semiconductor fundamentals. 1. The two types of semiconductor materials are P type and N type. N-type material contains extra electrons; P-type material contains holes due to missing electrons. The number of excess electrons in an N-type material must remain constant, and the number of holes in the P-type material must also remain constant. Because electrons are interchangeable, movement of electrons in or out of the material is possible to maintain a balanced material. 2. In P-type semiconductors, electrical conduction occurs mainly as the result of holes (absence of electrons). In N-type semiconductors, electrical conduction occurs mainly as the result of electrons (excess of electrons). 3. Hole movement results from the jumping of electrons into new positions. 4. Under the effect of a voltage applied to the semiconductor, electrons travel toward the positive terminal and holes move toward the negative terminal. The direction of hole current agrees with the conventional direction of current flow.
DIODES CONSTRUCTION A diode is an electrical one-way check valve made by combining a P-type material and an N-type material. The word diode means “having two electrodes.” Electrodes
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FIGURE 48–4 A diode is a component with P-type and N-type materials together. The negative electrode is called the cathode and the positive electrode is called the anode.
?
FREQUENTLY ASKED QUESTION
What Is the Hole Theory? Current flow is expressed as the movement of electrons from one atom to another. In semiconductor and electronic terms, the movement of electrons fills the holes of the P-type material. Therefore, as the holes are filled with electrons, the unfilled holes move opposite to the flow of the electrons. This concept of hole movement is called the hole theory of current flow. The holes move in the direction opposite that of electron flow. For example, think of an egg carton, where if an egg is moved in one direction, the holes created move in the opposite direction. SEE FIGURE 48–3.
are electrical connections: The positive electrode is called the anode; the negative electrode is called the cathode. The point where the two types of materials join is called the junction. SEE FIGURE 48–4.
OPERATION The N-type material has one extra electron, which can flow into the P-type material. The P type has a need for electrons to fill its holes. If a battery were connected to the diode positive (⫹) to P-type material and negative (⫺) to N-type material, then the electrons that left the N-type material and flowed into the P-type material to fill the holes would be quickly replaced by the electron
CATHODE CURRENT FLOW
NO CURRENT FLOW ANODE
ANODE P
N
DIODE CATHODE
DIODE
?
BATTERY
FIGURE 48–5 Diode connected to a battery with correct polarity (battery positive to P type and battery negative to N-type). Current flows through the diode. This condition is called forward bias.
CATHODE P N DIODE
ANODE
BATTERY
FIGURE 48–6 Diode connected with reversed polarity. No current flows across the junction between the P-type and N-type materials. This connection is called reverse bias.
flow from the battery. Current flows through a forward-bias diode for the following reasons.
FIGURE 48–7 Diode symbol and electrode names. The stripe on one end of a diode represents the cathode end of the diode.
Electrons move toward the holes (P-type material). Holes move toward the electrons (N-type material). SEE FIGURE 48–5.
As a result, current would flow through the diode with low resistance. This condition is called forward bias. If the battery connections were reversed and the positive side of the battery was connected to the N-type material, the electrons would be pulled toward the battery and away from the junction of the N-type and P-type materials. (Remember, unlike charges attract, whereas like charges repel.) Because electrical conduction requires the flow of electrons across the junction of the N-type and P-type materials and because the battery connections are actually reversed, the diode offers very high resistance to current flow. This condition is called reverse bias. SEE FIGURE 48–6. Therefore, diodes allow current flow only when current of the correct polarity is connected to the circuit.
Diodes are used in alternators to control current flow in one direction, which changes the AC voltage generated into DC voltage.
Diodes are also used in computer controls, relays, air-conditioning circuits, and many other circuits to prevent possible damage due to reverse current flows that may be generated within the circuit. SEE FIGURE 48–7.
FREQUENTLY ASKED QUESTION
What Is the Difference Between Electricity and Electronics? Electronics usually means that solid-state devices are used in the electrical circuits. Electricity as used in automotive applications usually means electrical current flow through resistance and loads without the use of diodes, transistors, or other electronic devices.
TECH TIP “Burn In” to Be Sure A common term heard in the electronic and computer industry is burn in, which means to operate an electronic device, such as a computer, for a period from several hours to several days. Most electronic devices fail in infancy, or during the first few hours of operation. This early failure occurs if there is a manufacturing defect, especially at the P-N junction of any semiconductor device. The junction will usually fail after only a few operating cycles. What does this information mean to the average person? When purchasing a personal or business computer, have the computer burned in before delivery. This step helps ensure that all of the circuits have survived infancy and that the chances of chip failure are greatly reduced. Purchasing sound or television equipment that has been on display may be a good value, because during its operation as a display model, the burn-in process has been completed. The automotive service technician should be aware that if a replacement electronic device fails shortly after installation, the problem may be a case of early electronic failure. NOTE: Whenever there is a failure of a replacement part, the technician should always check for excessive voltage or heat to and around the problem component.
ZENER DIODES CONSTRUCTION A zener diode is a specially constructed diode designed to operate with a reverse-bias current. Zener diodes were named in 1934 for their inventor, Clarence Melvin Zener, an American professor of physics. OPERATION A zener diode acts as any diode in that it blocks reverse-bias current, but only up to a certain voltage. Above this
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REVERSE CURRENT ANODE
CATHODE
ZENER DIODE SYMBOL
FIGURE 48–8 A zener diode blocks current flow until a certain voltage is reached, then it permits current to flow.
B SW
COIL
(a)
B
FIGURE 48–10 A diode connected to both terminals of the airconditioning compressor clutch used to reduce the high-voltage spike that results when a coil (compressor clutch coil) is de-energized. TO CONTROL CIRCUIT OR COMPUTER
(b)
FIGURE 48–9 (a) Notice that when the coil is being energized, the diode is reverse biased and the current is blocked from passing through the diode. The current flows through the coil in the normal direction. (b) When the switch is opened, the magnetic field surrounding the coil collapses, producing a high-voltage surge in the reverse polarity of the applied voltage. This voltage surge forward biases the diode, and the surge is dissipated harmlessly back through the windings of the coil. certain voltage (called the breakdown voltage or the zener region), a zener diode will conduct current in the opposite direction without damage to the diode. A zener diode is heavily doped, and the reverse-bias voltage does not harm the material. The voltage drop across a zener diode remains practically the same before and after the breakdown voltage, and this factor makes a zener diode perfect for voltage regulation. Zener diodes can be constructed for various breakdown voltages and can be used in a variety of automotive and electronic applications, especially for electronic voltage regulators used in the charging system. SEE FIGURE 48–8.
HIGH-VOLTAGE SPIKE PROTECTION CLAMPING DIODES Diodes can be used as a high-voltage clamping device when the power (⫹) is connected to the cathode (⫺) of the diode. If a coil is pulsed on and off, a high-voltage spike is produced whenever the coil is turned off. To control and direct this possibly damaging high-voltage spike, a diode can be installed across the leads to the coil to redirect the high-voltage spike back through the coil windings to prevent possible damage to the rest of the vehicle’s electrical or electronic circuits. A diode connected across the terminals of a coil to control voltage spikes is called a clamping diode. Clamping diodes can also be called despiking or suppression diodes. SEE FIGURE 48–9.
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RELAY CONTACTS
RELAY COIL WINDING
SPIKE PROTECTION DIODE
FIGURE 48–11 Spike protection diodes are commonly used in computer-controlled circuits to prevent damaging high-voltage surges that occur any time current flowing through a coil is stopped.
CLAMPING DIODE APPLICATION Diodes were first used on A/C compressor clutch coils at the same time electronic devices were first used. The diode was used to help prevent the high voltage spike generated inside the A/C clutch coil from damaging delicate to delicate electronic circuits anywhere in the vehicle’s electrical system. SEE FIGURE 48–10. Because most automotive circuits eventually are electrically connected to each other in parallel, a high-voltage surge anywhere in the vehicle could damage electronic components in other circuits. The circuits most likely to be affected by the high-voltage surge, if the diode fails, are the circuits controlling the operation of the A/C compressor clutch and any component that uses a coil, such as those of the blower motor and climate control units. Many relays are equipped with a diode to prevent a voltage spike when the contact points open and the magnetic field in the coil winding collapses. SEE FIGURE 48–11. DESPIKING ZENER DIODES
Zener diodes can also be used to control high-voltage spikes and keep them from damaging delicate electronic circuits. Zener diodes are most commonly used in electronic fuel-injection circuits that control the firing of the injectors. If clamping diodes were used in parallel with the injection coil, the resulting clamping action would tend to delay the closing of the
12 V
ELECTRONIC CONTROL UNIT
Resistors on coils are often used in relays and in climate-control circuit solenoids to control vacuum to the various air management system doors as well as other electronically controlled applications.
FUEL-INJECTOR COIL WINDING
ELECTRONIC SWITCH (TRANSISTOR)
DIODE RATINGS
CATHODE ANODE RS RESISTOR TO CONTROL CURRENT
35-V ZENER DIODE
SPECIFICATIONS
Most diodes are rated according to the
following:
FIGURE 48–12 A zener diode is commonly used inside automotive computers to protect delicate electronic circuits from highvoltage spikes. A 35 volt zener diode will conduct any voltage spike higher than 35 voltage resulting from the discharge of the fuel injector coil safely to ground through a current-limiting resistor in series with the zener diode.
Maximum current flow in the forward-bias direction. Diodes are sized and rated according to the amount of current they are designed to handle in the forward-bias direction. This rating is normally from 1 to 5 amperes for most automotive applications.
This rating of resistance to reverse-bias voltage is called the peak inverse voltage (PIV) rating, or the peak reverse voltage (PRV) rating. It is important that the service technician specifies and uses only a replacement diode that has the same or a higher rating than specified by the vehicle manufacturer for both amperage and PIV rating. Typical 1 A diodes use an industry numbering code that indicates the PIV rating. For example: 1N 4001-50 V PIV
RELAY CONTACTS
RELAY COIL WINDING
1N 4002-100 V PIV
SPIKE PROTECTION RESISTORS
1N 4003-200 V PIV (most commonly used) 1N 4004-400 V PIV 1N 4005-600 V PIV
FIGURE 48–13 A despiking resistor is used in many automotive applications to help prevent harmful high-voltage surges from being created when the magnetic field surrounding a coil collapses when the coil circuit is opened. fuel injector nozzle. A zener diode is commonly used to clamp only the higher voltage portion of the resulting voltage spike without affecting the operation of the injector. SEE FIGURE 48–12.
DESPIKING RESISTORS
All coils must use some protection against high-voltage spikes that occur when the voltage is removed from any coil. Instead of a diode installed in parallel with the coil windings, a resistor can be used, called a spike protection resistor. SEE FIGURE 48–13. Resistors are often preferred for two reasons.
Reason 1
Reason 2
Coils will usually fail when shorted rather than open, as this shorted condition results in greater current flow in the circuit. A diode installed in the reverse-bias direction cannot control this extra current, whereas a resistor in parallel can help reduce potentially damaging current flow if the coil becomes shorted. The protective diode can also fail, and diodes usually fail by shorting before they blow open. If a diode becomes shorted, excessive current can flow through the coil circuit, perhaps causing damage. A resistor usually fails open and, therefore, even in failure could not in itself cause a problem.
The “1N” means that the diode has one P-N junction. A higher rating diode can be used with no problems (except for slightly higher cost, even though the highest rated diode generally costs less than $1). Never substitute a lower rated diode than is specified.
DIODE VOLTAGE DROP
The voltage drop across a diode is about the same voltage as that required to forward bias the diode. If the diode is made from germanium, the forward voltage is 0.3 to 0.5 volt. If the diode is made from silicon, the forward voltage is 0.5 to 0.7 volt. NOTE: When diodes are tested using a digital multimeter, the meter will display the voltage drop across the P-N junction (about 0.5 to 0.7 volt) when the meter is set to the diodecheck position.
LIGHT-EMITTING DIODES OPERATION All diodes radiate some energy during normal operation. Most diodes radiate heat because of the junction barrier voltage drop (typically 0.6 volt for silicon diodes). Light emitting diode (LED) radiate light when current flows through the diode in the forward-bias direction. SEE FIGURE 48–14. The forward-bias voltage required for an LED ranges between 1.5 and 2.2 volts. An LED will only light if the voltage at the anode (positive electrode) is at least 1.5 to 2.2 volts higher than the voltage at the cathode (negative electrode).
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WINDOW ANODE METAL HOUSING PLASTIC
CATHODE
FIGURE 48–14 A typical light-emitting diode (LED). This particular LED is designed with a built-in resistor so that 12 volts DC may be applied directly to the leads without an external resistor. Normally a 300 to 500 ohm, 0.5 watt resistor is required to be attached in series with the LED, to control current flow to about 0.020 A (20 mA) or damage to the P-N junction may occur.
FIGURE 48–15 Typical photodiodes. They are usually built into a plastic housing so that the photodiode itself may not be visible.
FIGURE 48–16 Symbol for a photodiode. The arrows represent light striking the P-N junction of the photodiode.
?
FREQUENTLY ASKED QUESTION
How Does an LED Emit Light? An LED contains a chip that houses P-type and N-type materials. The junction between these regions acts as a barrier to the flow of electrons between the two materials. When a voltage of 1.5 to 2.2 volts of the correct polarity is applied, current will flow across the junction. As the electrons enter the P-type material, it combines with the holes in the material and releases energy in the form of light (called photons). The amount and color the light produces depends on materials used in the creation of the semiconductor material. LEDs are very efficient compared to conventional incandescent bulbs, which depend on heat to create light. LEDs generate very little heat, with most of the energy consumed converted directly to light. LEDs are reliable and are being used for taillights, brake lights, daytime running lights, and headlights in some vehicles.
NEED FOR CURRENT LIMITING
If an LED were connected across a 12 volt automotive battery, the LED would light brightly, but only for a second or two. Excessive current (amperes) that flows across the P-N junction of any electronic device can destroy the junction. A resistor must be connected in series with every diode (including LEDs) to control current flow across the P-N junction. This protection should include the following: 1. The value of the resistor should be from 300 to 500 ohms for each P-N junction. Commonly available resistors in this range include 470, 390, and 330 ohm resistors. 2. The resistors can be connected to either the anode or the cathode end. (Polarity of the resistor does not matter.) Current flows through the LED in series with the resistor, and the resistor will control the current flow through the LED regardless of its position in the circuit. 3. Resistors protecting diodes can be actual resistors or other current-limiting loads such as lamps or coils. With the current-limiting devices to control the current, the average LED will require about 20 to 30 milliamperes (mA), or 0.020 to 0.030 ampere.
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PHOTODIODES PURPOSE AND FUNCTION
All semiconductor P-N junctions emit energy, mostly in the form of heat or light such as with an LED. In fact, if an LED is exposed to bright light, a voltage potential is established between the anode and the cathode. Photodiodes are specially constructed to respond to various wavelengths of light with a “window” built into the housing. SEE FIGURE 48–15. Photodiodes are frequently used in steering wheel controls for transmitting tuning, volume, and other information from the steering wheel to the data link and the unit being controlled. If several photodiodes are placed on the steering column end and LEDs or phototransistors are placed on the steering wheel side, then data can be transmitted between the two moving points without the interference that could be caused by physical contact types of units.
CONSTRUCTION A photodiode is sensitive to light. When light energy strikes the diode, electrons are released and the diode will conduct in the forward-bias direction. (The light energy is used to overcome the barrier voltage.) The resistance across the photodiode decreases as the intensity of the light increases. This characteristic makes the photodiode a useful electronic device for controlling some automotive lighting systems such as automatic headlights. The symbol for a photodiode is shown in FIGURE 48–16.
PHOTORESISTORS A photoresistor is a semiconductor material (usually cadmium sulfide) that changes resistance with the presence or absence of light. Dark ⫽ High resistance Light ⫽ Low resistance Because resistance is reduced when the photoresistor is exposed to light, the photoresistor can be used to control headlight dimmer relays and for automotive headlights. SEE FIGURE 48–17.
LEFT BRAKE LIGHT
RIGHT BRAKE LIGHT DIODES (1N4003)
SCRs
GATE GATE
FIGURE 48–17 Either symbol may be used to represent a photoresistor.
ANODE ()
P
N
P
THIRD BRAKE LIGHT
CATHODE ()
N
GATE
470-Ω RESISTORS
FIGURE 48–19 Wiring diagram for a center high-mounted stoplight (CHMSL) using SCRs.
FIGURE 48–18 Symbol and terminal identification of an SCR.
SILICON-CONTROLLED RECTIFIERS T
CONSTRUCTION
A silicon-controlled rectifier (SCR) is commonly used in the electronic circuits of various automotive applications. An SCR is a semiconductor device that looks like two diodes connected end to end. SEE FIGURE 48–18. If the anode is connected to a higher voltage source than the cathode in a circuit, no current will flow as would occur with a diode. If, however, a positive voltage source is connected to the gate of the SCR, then current can flow from anode to cathode with a typical voltage drop of 1.2 volts (double the voltage drop of a typical diode, at 0.6 volt). Voltage applied to the gate is used to turn the SCR on. However, if the voltage source at the gate is shut off, the current will still continue to flow through the SCR until the source current is stopped.
USES OF AN SCR
SCRs can be used to construct a circuit for a center high-mounted stoplight (CHMSL). If this third stoplight were wired into either the left- or the right-side brake light circuit, the CHMSL would also flash whenever the turn signals were used for the side that was connected to the CHMSL. When two SCRs are used, both brake lights must be activated to supply current to the CHMSL. The current to the CHMSL is shut off when both SCRs lose their power source (when the brake pedal is released, which stops the current flow to the brake lights). SEE FIGURE 48–19.
THERMISTORS
FIGURE 48–20 Symbols used to represent a thermistor.
COPPER WIRE
NTC THERMISTOR
Cold
Lower resistance
Higher resistance
Hot
Higher resistance
Lower resistance
CHART 48–1 The resistance changes opposite that of a copper wire with changes in temperature.
to a thermistor, its resistance decreases because the thermistor itself is acting as a current carrier rather than as a resistor at higher temperatures.
USES OF THERMISTORS
A thermistor is commonly used as a temperature-sensing device for coolant temperature and intake manifold air temperature. Because thermistors operate in a manner opposite to that of a typical conductor, they are called negative temperature coefficient (NTC) thermistors; their resistance decreases as the temperature increases. SEE CHART 48–1. Thermistor symbols are shown in FIGURE 48–20.
RECTIFIER BRIDGES
CONSTRUCTION
A thermistor is a semiconductor material such as silicon that has been doped to provide a given resistance. When the thermistor is heated, the electrons within the crystal gain energy and electrons are released. This means that a thermistor actually produces a small voltage when heated. If voltage is applied
DEFINITION
The word rectify means “to set straight”; therefore, a rectifier is an electronic device (such as a diode) used to convert a changing voltage into a straight or constant voltage. A rectifier bridge is a group of diodes that is used to change alternating current
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n
p
n
p
n
COLLECTOR
EMITTER
COLLECTOR
EMITTER BASE
FIGURE 48–21 This rectifier bridge contains six diodes; the three on each side are mounted in an aluminum-finned unit to help keep the diode cool during alternator operation.
(AC) into direct current (DC). A rectifier bridge is used in alternators to rectify the AC voltage produced in the stator (stationary windings) of the alternator into DC voltage. These rectifier bridges contain six diodes: one pair of diodes (one positive and one negative) for each of the three stator windings. SEE FIGURE 48–21.
TRANSISTORS PURPOSE AND FUNCTION
A transistor is a semiconductor device that can perform the following electrical functions.
P
N EMITTER
BASE
N
P
COLLECTOR
p
N
EMITTER
BASE
P COLLECTOR
BASE
FIGURE 48–22 Basic transistor operation. A small current flowing through the base and emitter of the transistor turns on the transistor and permits a higher amperage current to flow from the collector and the emitter.
RELAY
TRANSISTOR
Low-current circuit
Coil (terminals 85 and 86)
Base and emitter
High-current circuit
Contacts terminals 30 and 87
Collector and emitter
1. Act as an electrical switch in a circuit 2. Act as an amplifier of current in a circuit 3. Regulate the current in a circuit The word transistor, derived from the words transfer and resistor, is used to describe the transfer of current across a resistor. A transistor is made of three alternating sections or layers of P-type and N-type materials. This type of transistor is usually called a bipolar transistor.
CHART 48–2 Comparison between the control (low-current) and high-current circuits of a transistor compared to a mechanical relay.
?
FREQUENTLY ASKED QUESTION
Is a Transistor Similar to a Relay?
CONSTRUCTION A transistor that has P-type material on each end, with N-type material in the center, is called a PNP transistor. Another type, with the exact opposite arrangement, is called an NPN transistor. The material at one end of a transistor is called the emitter and the material at the other end is called the collector. The base is in the center and the voltage applied to the base is used to control current through a transistor. TRANSISTOR SYMBOLS
Yes, in many cases a transistor is similar to a relay. Both use a low current to control a higher current circuit. SEE CHART 48–2. A relay can only be on or off. A transistor can provide a variable output if the base is supplied a variable current input.
?
All transistor symbols contain an arrow indicating the emitter part of the transistor. The arrow points in the direction of current flow (conventional theory). When an arrowhead appears in any semiconductor symbol, it stands for a P-N junction and it points from the P-type material toward the N-type material. The arrow on a transistor is always attached to the emitter side of the transistor. SEE FIGURE 48–22.
What Does the Arrow Mean on a Transistor Symbol?
HOW A TRANSISTOR WORKS A transistor is similar to two back-to-back diodes that can conduct current in only one direction. As in a diode, N-type material can conduct electricity by means of its supply of free electrons, and P-type material conducts by means of its supply of positive holes.
• PNP: pointing in • NPN: not pointing in
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CHAPTER 4 8
FREQUENTLY ASKED QUESTION
The arrow on a transistor symbol is always on the emitter and points toward the N-type material. The arrow on a diode also points toward the N-type material. To know which type of transistor is being shown, note which direction the arrow points.
THEN THIS (HIGHER CURRENT)
DRAIN
DRAIN
N-CHANNEL TYPE
N P
GATE EMITTER E
COLLECTOR C
IF THIS (LOW CURRENT)
P
GATE
N SOURCE
SOURCE
DRAIN
DRAIN
P-CHANNEL TYPE
P N
GATE
N
GATE
P BASE B
FIGURE 48–23 Basic transistor operation. A small current flowing through the base and emitter of the transistor turns on the transistor and permits a higher amperage current to flow from the collector and the emitter.
A transistor will allow current flow if the electrical conditions allow it to switch on, in a manner similar to the working of an electromagnetic relay. The electrical conditions are determined, or switched, by means of the base, or B. The base will carry current only when the proper voltage and polarity are applied. The main circuit current flow travels through the other two parts of the transistor: the emitter E and the collector C. SEE FIGURE 48–23. If the base current is turned off or on, the current flow from collector to emitter is turned off or on. The current controlling the base is called the control current. The control current must be high enough to switch the transistor on or off. (This control voltage, called the threshold voltage, must be above approximately 0.3 volt for germanium and 0.6 volt for silicon transistors.) This control current can also “throttle” or regulate the main circuit, in a manner similar to the operation of a water faucet.
HOW A TRANSISTOR AMPLIFIES A transistor can amplify a signal if the signal is strong enough to trigger the base of a transistor on and off. The resulting on-off current flow through the transistor can be connected to a higher powered electrical circuit. This results in a higher powered circuit being controlled by a lower powered circuit. This low-powered circuit’s cycling is exactly duplicated in the higher powered circuit, and therefore any transistor can be used to amplify a signal. However, because some transistors are better than others for amplification, specialized types of transistors are used for each specialized circuit function.
SOURCE
SOURCE
FIGURE 48–24 The three terminals of a field-effect transistor (FET) are called the source, gate, and drain.
FIGURE 48–25 A Darlington pair consists of two transistors wired together, allowing for a very small current to control a larger current flow circuit.
?
FREQUENTLY ASKED QUESTION
What Is a Darlington Pair? A Darlington pair consists of two transistors wired together. This arrangement permits a very small current flow to control a large current flow. The Darlington pair is named for Sidney Darlington, an American physicist for Bell Laboratories from 1929 to 1971. Darlington amplifier circuits are commonly used in electronic ignition systems, computer engine control circuits, and many other electronic applications. SEE FIGURE 48–25.
FIELD-EFFECT TRANSISTORS Field-effect transistors (FETs) have been used in most automotive applications since the mid-1980s. They use less electrical current and rely mostly on the strength of a small voltage signal to control the output. The parts of a typical FET include the source, gate, and drain. SEE FIGURE 48–24. Many field-effect transistors are constructed of metal oxide semiconductor (MOS) materials, called MOSFETs. MOSFETs are highly sensitive to static electricity and can be easily damaged if exposed to excessive current or high-voltage surges (spikes). Most
automotive electronic circuits use MOSFETs, which explains why it is vital for the service technician to use caution to avoid doing anything that could result in a high-voltage spike, and perhaps destroy an expensive computer module. Some vehicle manufacturers recommend that technicians wear an antistatic wristband when working with modules that contain MOSFETs. Always follow the vehicle manufacturer’s instructions found in service information to avoid damaging electronic modules or circuits.
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C
C
?
E
What Causes a Transistor or Diode to Blow?
B E
(a)
(b)
FIGURE 48–26 Symbols for a phototransistor. (a) This symbol uses the line for the base; (b) this symbol does not.
CAPACITORS PROM ICs
CENTRAL PROCESSING UNIT (CPU)
FREQUENTLY ASKED QUESTION
Every automotive diode and transistor is designed to operate within certain voltage and amperage ranges for individual applications. For example, transistors used for switching are designed and constructed differently from transistors used for amplifying signals. Because each electronic component is designed to operate satisfactorily for its particular application, any severe change in operating current (amperes), voltage, or heat can destroy the junction. This failure can cause either an open circuit (no current flows) or a short (current flows through the component all the time when the component should be blocking the current flow).
Therefore, most computer circuits are housed as an integrated circuit in a DIP chip.
FIGURE 48–27 A typical automotive computer with the case removed to show all of the various electronic devices and integrated circuits (ICs). The CPU is an example of a DIP chip and the large red and orange devices are ceramic capacitors.
PHOTOTRANSISTORS Similar in operation to a photodiode, a phototransistor uses light energy to turn on the base of a transistor. A phototransistor is an NPN transistor that has a large exposed base area to permit light to act as the control for the transistor. Therefore, a phototransistor may or may not have a base lead. If not, then it has only a collector and emitter lead. When the phototransistor is connected to a powered circuit, the light intensity is amplified by the gain of the transistor. Phototransistors, along with photo diodes, are frequently used in steering wheel controls. SEE FIGURE 48–26.
INTEGRATED CIRCUITS PURPOSE AND FUNCTION Solid-state components are used in many electronic semiconductors and/or circuits. They are called “solid state” because they have no moving parts, just higher or lower voltage levels within the circuit. Discrete (individual) diodes, transistors, and other semiconductor devices were often used to construct early electronic ignition and electronic voltage regulators. Newer style electronic devices use the same components, but they are now combined (integrated) into one group of circuits, and are thus called an integrated circuit (IC). CONSTRUCTION Integrated circuits are usually encased in a plastic housing called a CHIP with two rows of inline pins. This arrangement is called the dual inline pins (DIP) chips. SEE FIGURE 48–27.
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HEAT SINK Heat sink is a term used to describe any area around an electronic component that, because of its shape or design, can conduct damaging heat away from electronic parts. Examples of heat sinks include the following: 1. Ribbed electronic ignition control units 2. Cooling slits and cooling fan attached to an alternator 3. Special heat-conducting grease under the electronic ignition module in General Motors HEI distributor ignition systems and other electronic systems Heat sinks are necessary to prevent damage to diodes, transistors, and other electronic components due to heat buildup. Excessive heat can damage the junction between the N-type and P-type materials used in diodes and transistors.
TRANSISTOR GATES PURPOSE AND FUNCTION An understanding of the basic operation of electronic gates is important to understanding how computers work. A gate is an electronic circuit whose output depends on the location and voltage of two inputs. CONSTRUCTION Whether a transistor is on or off depends on the voltage at the base of the transistor. If the voltage is at least a 0.6 volt difference from that of the emitter, the transistor is turned on. Most electronic and computer circuits use 5 volts as a power source. If two transistors are wired together, several different outputs can be received depending on how the two transistors are wired. SEE FIGURE 48–28. OPERATION
If the voltage at A is higher than that of the emitter, the top transistor is turned on; however, the bottom transistor is off unless the voltage at B is also higher. If both transistors are turned on, the output signal voltage will be high. If only one of the two transistors is on, the output will be zero (off or no voltage). Because it requires both A and B to be on to result in a voltage output, this circuit is called an AND gate. In other words, both transistors have
FIGURE 48–29 Symbol for an operational amplifier (op-amp).
on when the following events occur, to cause the control module to turn it on. 1. The ignition must be on (input). 2. The air conditioning is commanded on. FIGURE 48–28 Typical transistor AND gate circuit using two transistors. The emitter is always the line with the arrow. Notice that both transistors must be turned on before there will be voltage present at the point labeled “signal out.”
?
FREQUENTLY ASKED QUESTION
3. The engine coolant temperature is within a predetermined limit. If all of these conditions are met, then the control module will command the blower motor on. If any of the input signals are incorrect, the control module will not be able to perform the correct command.
OPERATIONAL AMPLIFIERS
What Are Logic Highs and Lows? All computer circuits and most electronic circuits (such as gates) use various combinations of high and low voltages. High voltages are typically those above 5 volts, and low is generally considered zero (ground). However, high voltages do not have to begin at 5 volts. High, or the number 1, to a computer is the presence of voltage above a certain level. For example, a circuit could be constructed where any voltage higher than 3.8 volts would be considered high. Low, or the number 0, to a computer is the absence of voltage or a voltage lower than a certain value. For example, a voltage of 0.62 may be considered low. Various associated names and terms can be summarized. • Logic low ⫽ Low voltage ⫽ Number 0 ⫽ Reference low • Logic high ⫽ Higher voltage ⫽ Number 1 ⫽ Reference high
Operational amplifiers (op-amps) are used in circuits to control and amplify digital signals. Op-amps are frequently used for motor control in climate control systems (heating and air conditioning) airflow control door operation. Op-amps can provide the proper voltage polarity and current (amperes) to control the direction of permanent magnetic (PM) motors. The symbol for an op-amp is shown in FIGURE 48–29.
ELECTRONIC COMPONENT FAILURE CAUSES Electronic components such as electronic ignition modules, electronic voltage regulators, onboard computers, and any other electronic circuit are generally quite reliable; however, failure can occur. Frequent causes of premature failure include the following:
to be on before the gate opens and allows a voltage output. Other types of gates can be constructed using various connections to the two transistors. For example:
AND gate. Requires both transistors to be on to get an output.
NOTE: When cleaning electronic contacts, use a pencil eraser. This cleans the contacts without harming the thin, protective coating used on most electronic terminals.
OR gate. Requires either transistor to be on to get an output. NAND (NOT-AND) gate. Output is on unless both transistors are on. NOR (NOT-OR) gate. Output is on only when both transistors are off. Gates represent logic circuits that can be constructed so that the output depends on the voltage (on or off; high or low) of the inputs to the bases of transistors. Their inputs can come from sensors or other circuits that monitor sensors, and their outputs can be used to operate an output device if amplified and controlled by other circuits. For example, the blower motor will be commanded
Poor connections. It has been estimated that most engine computers returned as defective have simply had poor connections at the wiring harness terminal ends. These faults are often intermittent and hard to find.
Heat. The operation and resistance of electronic components and circuits are affected by heat. Electronic components should be kept as cool as possible and never hotter than 260°F (127°C).
Voltage spikes. A high-voltage spike can literally burn a hole through semiconductor material. The source of these highvoltage spikes is often the discharge of a coil without proper (or with defective) despiking protection. A poor electrical
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BLINKING LED THEFT DETERRENT*
TECH TIP
RED LED STARTS TO FLASH WHENEVER IGNITION IS TURNED OFF
Blinking LED Theft Deterrent A blinking (flashing) LED consumes only about 5 milliamperes (5/1,000 of 1 ampere or 0.005 A). Most alarm systems use a blinking red LED to indicate that the system is armed. A fake alarm indicator is easy to make and install. A 470 ohm, 0.5 watt resistor limits current flow to prevent battery drain. The positive terminal (anode) of the diode is connected to a fuse that is hot at all times, such as the cigarette lighter. The negative terminal (cathode) of the LED is connected to any ignition-controlled fuse. SEE FIGURE 48–30. When the ignition is turned off, the power flows through the LED to ground and the LED flashes. To prevent distraction during driving, the LED goes out when the ignition is on. Therefore, this fake theft deterrent is “auto setting” and no other action is required to activate it when you leave your vehicle except to turn off the ignition and remove the key as usual.
connection at the battery or other major electrical connection can cause high-voltage spikes to occur, because the entire wiring harness creates its own magnetic field, similar to that formed around a coil. If the connection is loose and momentary loss of contact occurs, a high-voltage surge can occur through the entire electrical system. To help prevent this type of damage, ensure that all electrical connections, including grounds, are properly clean and tight.
470 OHM 1/2 WATT RESISTOR P.N. 271-1115
BLINKING LED P.N. 276-036
FUSE PANEL *ALL PART NUMBERS ARE FROM RADIO SHACK
FIGURE 48–30 Schematic for a blinking LED theft deterrent.
HOW TO TEST DIODES AND TRANSISTORS TESTERS Diodes and transistors can be tested with an ohmmeter. The diode or transistor being tested must be disconnected from the circuit for the results to be meaningful.
CAUTION: One of the major causes of electronic failure occurs during jump starting a vehicle. Always check that the ignition switch is off on both vehicles when making the connection. Always double check that the correct battery polarity (⫹ to ⫹ and ⫺ to ⫺) is being performed.
Excessive current. All electronic circuits are designed to operate within a designated range of current (amperes). If a solenoid or relay is controlled by a computer circuit, the resistance of that solenoid or relay becomes part of that control circuit. If a coil winding inside the solenoid or relay becomes shorted, the resulting lower resistance will increase the current through the circuit. Even though individual components are used with current-limiting resistors in series, the coil winding resistance is also used as a current-control component in the circuit. If a computer fails, always measure the resistance across all computer-controlled relays and solenoids. The resistance should be within specifications (generally over 20 ohms) for each component that is computer controlled.
NOTE: Some computer-controlled solenoids are pulsed on and off rapidly. This type of solenoid is used in many electronically shifted transmissions. Their resistance is usually about half of the resistance of a simple on-off solenoid— usually between 10 and 15 ohms. Because the computer controls the on-time of the solenoid, the solenoid and its circuit control are called pulse-width modulated (PWM).
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ANY IGNITION-CONTROLLED FUSE SUCH AS IGNITION, WIPER, ETC. NOTE: OPTIONAL FUSE TAPS P.N. 270-1204
HOT ALL TIMES SUCH AS CLOCK, LIGHTER, ETC.
Use the diode-check position on a digital multimeter.
In the diode-check position on a digital multimeter, the meter applies a higher voltage than when the ohms test function is selected.
This slightly higher voltage (about 2 to 3 volts) is enough to forward bias a diode or the P-N junction of transistors.
DIODES Using the diode test position, the meter applies a voltage. The display will show the voltage drop across the diode P-N junction. A good diode should give an over limit (OL) reading with the test leads attached to each lead of the diode in one way, and a voltage reading of 0.400 to 0.600 V when the leads are reversed. This reading is the voltage drop or the barrier voltage across the P-N junction of the diode. 1. A low-voltage reading with the meter leads attached both ways across a diode means that the diode is shorted and must be replaced. 2. An OL reading with the meter leads attached both ways across a diode means that the diode is open and must be replaced. SEE FIGURE 48–31.
TRANSISTORS Using a digital meter set to the diode-check position, a good transistor should show a voltage drop of 0.400 to 0.600 volt between the following:
The emitter (E) and the base (B) and between the base (B) and the collector (C) with a meter connected one way, and OL when the meter test leads are reversed.
14 V (B+)
PCM
0.516
REFERENCE VOLTAGE (5V - V-REF)
A B
5V
DC TO DC CONVERTER
SIGNAL GROUND
C
ANODE
CATHODE
(a)
FIGURE 48–33 A DC to DC converter is built into most powertrain control modules (PCMs) and is used to supply the 5 volt reference called V-ref to many sensors used to control the internal combustion engine.
O.L.
THROTTLE POSITION (TP) SENSOR
TRANSFORMER
42 V
ANODE
LOAD
FEEDBACK CONTROL CIRCUIT
CATHODE
(b) FIGURE 48–31 To check a diode, select “diode check” on a digital multimeter. The display will indicate the voltage drop (difference) between the meter leads. The meter itself applies a low-voltage signal (usually about 3 volts) and displays the difference on the display. (a) When the diode is forward biased, the meter should display a voltage between 0.500 and 0.700 V (500 to 700 mV). (b) When the meter leads are reversed, the meter should read OL (over limit) because the diode is reverse biased and blocking current flow.
14 V
FIGURE 48–34 This DC-DC converter is designed to convert 42 volts to 14 volts, to provide 14 V power to accessories on a hybrid electric vehicle operating with a 42 volt electrical system.
CONVERTERS AND INVERTERS CONVERTERS
DC to DC converters (usually written as DC-DC converter) are electronic devices used to transform DC voltage from one level of DC voltage to another higher or lower level. They are used to distribute various levels of DC voltage throughout a vehicle from a single power bus (or voltage source).
FIGURE 48–32 If the red (positive) lead of the ohmmeter (or a multimeter set to diode check) is touched to the center and the black (negative lead) touched to either end of the electrode, the meter should forward bias the P-N junction and indicate on the meter as low resistance. If the meter reads high resistance, reverse the meter leads, putting the black on the center lead and the red on either end lead. If the meter indicates low resistance, the transistor is a good PNP type. Check all P-N junctions in the same way.
An OL reading (no continuity) in both directions when a transistor is tested between the emitter (E) and the collector (C) (A transistor tester can also be used if available.). SEE FIGURE 48–32.
EXAMPLES OF USE One example of a DC-DC converter circuit is the circuit the PCM uses to convert 14 V to 5 V. The 5 volts is called the reference voltage, abbreviated V-ref, and is used to power many sensors in a computer-controlled engine management system. The schematic of a typical 5 volt V-ref interfacing with the TP sensor circuit is shown in FIGURE 48–33. The PCM operates on 14 volts, using the principle of DC conversion to provide a constant 5 volts of sensor reference voltage to the TP sensor and others. The TP sensor demands little current, so the V-ref circuit is a low-power DC voltage converter in the range of 1 watt. The PCM uses a DC-DC converter, which is a small semiconductor device called a voltage regulator, and is designed to convert battery voltage to a constant 5 volts regardless of changes in the charging voltage. Hybrid electric vehicles use DC-DC converters to provide higher or lower DC voltage levels and current requirements. A high-power DC-DC converter schematic is shown in FIGURE 48–34 and represents how a nonelectronic DC-DC converter works.
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SENSING FOR OUTPUT REGULATION DC INPUT
FUSE
BATTERY
MOSFET AC OUTPUT
MOSFET DRIVING CIRCUIT TRANSFORMER ZENER DIODE
(SENSING FOR AUTO TURN-ON)
FIGURE 48–35 A typical circuit for an inverter designed to change direct current from a battery to alternating current for use by the electric motors used in a hybrid electric vehicle. The central component of a converter is a transformer that physically isolates the input (42 V) from the output (14 V). The power transistor pulses the high-voltage coil of the transformer, and the resulting changing magnetic field induces a voltage in the coil windings of the lower voltage side of the transformer. The diodes and capacitors help control and limit the voltage and frequency of the circuit.
DC-DC CONVERTER CIRCUIT TESTING Usually a DC control voltage is used, which is supplied by a digital logic circuit to shift the voltage level to control the converter. A voltage test can indicate if the correct voltages are present when the converter is on and off. WARNING Always follow the manufacturer’s safety precautions for discharging capacitors in DC-DC converter circuits.
Voltage measurements are usually specified to diagnose a DC-DC converter system. A digital multimeter (DMM) that is CAT III rated should be used. 1. Always follow the manufacturer’s safety precautions when working with high-voltage circuits. These circuits are usually indicated by orange wiring. 2. Never tap into wires in a DC-DC converter circuit to access power for another circuit. 3. Never tap into wires in a DC-DC converter circuit to access a ground for another circuit.
PEAK TO PEAK VOLTAGE
FIGURE 48–36 The switching (pulsing) MOSFETs create a waveform called a modified sine wave (solid lines) compared to a true sine wave (dotted lines).
INVERTERS An inverter is an electronic circuit that changes direct current (DC) into alternating current (AC). In most DC-AC inverters, the switching transistors, which are usually MOSFETs, are turned on alternately for short pulses. As a result, the transformer produces a modified sine wave output, rather than a true sine wave. SEE FIGURE 48–35. The waveform produced by an inverter is not the perfect sine wave of household AC, but is rather more like a pulsing DC that reacts similar to sine wave AC in transformers and in induction motors. SEE FIGURE 48–36. Inverters power AC motors. An inverter converts DC power to AC power at the required frequency and amplitude. The inverter consists of three half-bridge units, and the output voltage is mostly created by a pulse-width modulation (PWM) technique. The threephase voltage waves are shifted 120 degrees to each other, to power each of the three phases.
WARNING
4. Never block airflow to a DC-DC converter heat sink. 5. Never use a heat sink for a ground connection for a meter, scope, or accessory connection. 6. Never connect or disconnect a DC-DC converter while the converter is powered up. 7. Never connect a DC-DC converter to a larger voltage source than specified.
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Do not touch the terminals of a battery that are being used to power an inverter. There is always a risk that those battery terminals could deliver a much greater shock than from batteries alone, if a motor or inverter should develop a fault.
ELECTROSTATIC DISCHARGE DEFINITION
Electrostatic discharge (ESD) is created when static charges build up on the human body when movement occurs. The friction of the clothing and the movement of shoes against carpet or vinyl floors cause a high voltage to build. Then when we touch a conductive material, such as a doorknob, the static charge is rapidly discharged. These charges, although just slightly painful to us, can cause severe damage to delicate electronic components. The following are typical static voltages.
If you can feel it, it is at least 3,000 volts.
If you can hear it, it is at least 5,000 volts.
If you can see it, it is at least 10,000 volts.
Although these voltages seem high, the current, in amperes, is extremely low. However, sensitive electronic components such as vehicle computers, radios, and instrument panel clusters can
be ruined if exposed to as little as 30 volts. This is a problem, because harm can occur to components at voltages lower than we can feel.
AVOIDING ESD
To help prevent damage to components, follow
these easy steps. 1. Keep the replacement electronic component in the protective wrapping until just before installation. 2. Before handling any electronic component, ground yourself by touching a metal surface to drain away any static charge. 3. Do not touch the terminals of electronic components. 4. If working in an area where touching terminals may occur, wear a static electrically grounding wrist strap available at most electronic parts stores, such as Radio Shack. If these precautions are observed, ESD damage can be eliminated or reduced. Remember, just because the component works after being touched does not mean that damage has not occurred. Often, a section of the electronic component may be damaged, yet will not fail until several days or weeks later.
REVIEW QUESTIONS 1. What is the difference between P-type material and N-type material? 2. How can a diode be used to suppress high-voltage surges in automotive components or circuits containing a coil?
3. How does a transistor work? 4. To what precautions should all service technicians adhere, to avoid damage to electronic and computer circuits?
CHAPTER QUIZ 1. A semiconductor is a material ______________. a. With fewer than four electrons in the outer orbit of its atoms b. With more than four electrons in the outer orbit of its atoms c. With exactly four electrons in the outer orbit of its atoms d. Determined by other factors besides the number of electrons 2. The arrow in a symbol for a semiconductor device ______________. a. Points toward the negative b. Points away from the negative c. Is attached to the emitter on a transistor d. Both a and c 3. A diode installed across a coil with the cathode toward the battery positive is called a(n) ______________. a. Clamping diode c. SCR b. Forward-bias diode d. Transistor 4. A transistor is controlled by the polarity and current at the ______________. a. Collector c. Base b. Emitter d. Both a and b 5. A transistor can ______________. a. Switch on and off c. Throttle b. Amplify d. All of the above
6. Clamping diodes ______________. a. Are connected into a circuit with the positive (⫹) voltage source to the cathode and the negative (⫺) voltage to the anode b. Are also called despiking diodes c. Can suppress transient voltages d. All of the above 7. A zener diode is normally used for voltage regulation. A zener diode, however, can also be used for high-voltage spike protection if connected ______________. a. Positive to anode, negative to cathode b. Positive to cathode, ground to anode c. Negative to anode, cathode to a resistor then to a lower voltage terminal d. Both a and c 8. The forward-bias voltage required for an LED is ______________. a. 0.3 to 0.5 volt c. 1.5 to 2.2 volts b. 0.5 to 0.7 volt d. 4.5 to 5.1 volts 9. An LED can be used in a ______________. a. Headlight c. Brake light b. Taillight d. All of the above 10. Another name for a ground is ______________. a. Logic low c. Reference low b. Zero d. All of the above
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chapter
49
CAN AND NETWORK COMMUNICATIONS
OBJECTIVES: After studying Chapter 49, the reader should be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “A” (General Electrical/Electronic Systems Diagnosis). • Describe the types of networks and serial communications used on vehicles. • Discuss how the networks connect to the data link connector and to other modules. • Explain how to diagnose module communication faults. KEY TERMS: Breakout box (BOB) 533 • BUS 526 • CAN 527 • Chrysler Collision Detection (CCD) 530 • Class 2 528 • E & C 528 • GMLAN 528 • Keyword 528 • Multiplexing 524 • Network 524 • Node 524 • Plastic optical fiber (POF) 534 • Programmable controller interface (PCI) 530 • Protocol 527 • Serial communications interface (SCI) 530 • Serial data 524 • Splice pack 525 • Standard corporate protocol (SCP) 529 • State of health (SOH) 534 • SWCAN 529 • Terminating resistors 534 • Twisted pair 524 • UART 527 • UART-based protocol (UBP) 530
MODULE COMMUNICATIONS AND NETWORKS NEED FOR NETWORK Since the 1990s, vehicles have used modules to control the operation of most electrical components. A typical vehicle will have 10 or more modules and they communicate with each other over data lines or hard wiring, depending on the application.
the task by supplying power and ground to the window lift motor in the current polarity to cause the window to go down. The module also contains a circuit that monitors the current flow through the motor and will stop and/or reverse the window motor if an obstruction causes the window motor to draw more than the normal amount of current.
TYPES OF COMMUNICATION
Differential. In the differential form of module communication, a difference in voltage is applied to two wires, which are twisted to help reduce electromagnetic interference (EMI). These transfer wires are called a twisted pair.
Parallel. In the parallel type of module communication, the send and receive signals are on different wires.
Serial data. The serial data is data transmitted over one wire by a series of rapidly changing voltage signals pulsed from low to high or from high to low.
Multiplexing. The process of multiplexing involves the sending of multiple signals of information at the same time over a signal wire and then separating the signals at the receiving end.
ADVANTAGES Most modules are connected together in a network because of the following advantages.
A decreased number of wires are needed, thereby saving weight and cost, as well as helping with installation at the factory and decreased complexity, making servicing easier. Common sensor data can be shared with those modules that may need the information, such as vehicle speed, outside air temperature, and engine coolant temperature.
SEE FIGURE 49–1.
NETWORK FUNDAMENTALS MODULES AND NODES
Each module, also called a node, must communicate to other modules. For example, if the driver depresses the window-down switch, the power window switch sends a window-down message to the body control module. The body control module then sends the request to the driver’s side window module. This module is responsible for actually performing
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CHAPTER 4 9
The types of communications
include the following:
This system of intercommunication of computers or processors is referred to as a network. SEE FIGURE 49–2. By connecting the computers together on a communications network, they can easily share information back and forth. This multiplexing has the following advantages.
Elimination of redundant sensors and dedicated wiring for these multiple sensors
Reduction of the number of wires, connectors, and circuits
Addition of more features and option content to new vehicles
CONVENTIONAL WIRING BETWEEN COMPONENTS
M
MOTOR
LIGHT
HEATER
FIGURE 49–1 Module communications makes controlling multiple electrical devices and accessories easier by utilizing simple low-current switches to signal another module, which does the actual switching of the current to the device.
SOLENOID SWITCH
ECU
ECU
M
MOTOR
DISCRETE SIGNALS M
L
H
S
MPX COMMUNICATION LINE
LIGHT
HEATER
SOLENOID SWITCH
PROGRAMMED TO USE VEHICLE SPEED SIGNAL POWERTRAIN CONTROL MODULE (PCM)
CRUISE CONTROL MODULE
MODULE COMMUNICATIONS CONFIGURATION The three most common types of networks used on vehicles include: 1. Ring link networks. In a ring-type network, all modules are connected to each other by a serial data line (in a line) until all are connected in a ring. SEE FIGURE 49–3.
DRIVER'S DOOR MODULE (DDM)
ANTI-LOCK BRAKE CONTROL MODULE
PROGRAMMED TO USE VEHICLE SPEED SIGNAL
FIGURE 49–2 A network allows all modules to communicate with other modules.
Weight reduction due to fewer components, wires, and connectors, thereby increasing fuel economy
Changeable features with software upgrades versus component replacement
2. Star link networks. In a star link network, a serial data line attaches to each module and then each is connected to a central point. This central point is called a splice pack, abbreviated SP such as in “SP 306.” The splice pack uses a bar to splice all of the serial lines together. Some GM vehicles use two or more splice packs to tie the modules together. When more than one splice pack is used, a serial data line connects one splice pack to the others. In most applications, the BUS bar used in each splice pack can be removed. When the BUS bar is removed, a special tool (J 42236) can be installed in place of the removed BUS bar. Using this tool, the serial data line for each module can be isolated and tested for a possible problem. Using the special tool at the splice pack makes diagnosing this type of network easier than many others. SEE FIGURE 49–4. 3. Ring/star hybrid. In a ring/star network, the modules are connected using both types of network configurations. Check service information (SI) for details on how this network is connected on the vehicle being diagnosed and always follow the recommended diagnostic steps.
C AN AN D N E T W O RK C O MM U N IC A T ION S
525
LH DOOR CONTROL MODULE
INSTRUMENT CLUSTER
ELECTRONIC BRAKE CONTROL MODULE (EBCM)
POWERTRAIN CONTROL MODULE (PCM)
RADIO
REAR INTEGRATION MODULE (RIM)
REMOTE FUNCTION ACTUATOR (RFA)
VEHICLE INTERFACE MODULE (VIM)
MEMORY SEAT MODULE (MSM)
HEATER AND A/C CONTROL
HEAD UP DISPLAY (HUD) PIN 1 VEHICLE THEFT DETERRENT MODULE
INSTRUMENT PANEL MODULE (IPM)
DLC
COMPACT DISC (CD) CHANGER
PIN 16 DASH INTEGRATION MODULE (DIM)
SENSING DIAGNOSTIC MODULE (SDM)
FIGURE 49–3 A ring link network reduces the number of wires it takes to interconnect all of the modules. CLASS C SPLICE PACK
SPLICE PACK LH DOOR CONTROL MODULE
POWERTRAIN CONTROL MODULE (PCM)
RH DOOR CONTROL MODULE
THROTTLE ACTUATOR CONTROL (TAC) MODULE
ELECTRONIC BRAKE/ TRACTION CONTROL (EBTCM)
LH SEAT CONTROL MODULE
CLASS 2 ELECTRONIC SUSPENSION CONTROL (ESC) MODULE PIN 1 DLC HVAC PROGRAMMER MODULE UART
PIN 16 BODY CONTROL MODULE (BCM)
SENSING DIAGNOSTIC MODULE (SDM)
COMPACT DISC (CD) CHANGER
IP ELECTRICAL CENTER
E&C BUSS
AUDIO SYSTEM RADIO
REMOTE CONTROL DOOR LOCK MODULE
INSTRUMENT CLUSTER
FIGURE 49–4 In a star link network, all of the modules are connected using splice packs.
NETWORK COMMUNICATIONS CLASSIFICATIONS
?
FREQUENTLY ASKED QUESTION
What Is a BUS? The Society of Automotive Engineers (SAE) standards include the following three categories of in-vehicle network communications.
CLASS A
Low-speed networks, meaning less than 10,000 bits per second (bps, or 10 Kbs), are generally used for trip computers, entertainment, and other convenience features.
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A BUS is a term used to describe a communications network. Therefore, there are connections to the BUS and BUS communications, both of which refer to digital messages being transmitted among electronic modules or computers.
FIGURE 49–5 A typical BUS system showing module CAN communications and twisted pairs of wire.
CAN C DIAGNOSTIC + 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
CAN C DIAGNOSTIC –
CAN B+
CAN B–
SCAN TOOL
AIR BAG MODULE CAN B–
CAN B–
CAN B+
CAN B+
REMOTE KEYLESS ENTRY
RIGHT FRT. DOOR MODULE
CAN B–
CAN B–
CAN B+
CAN B+
RADIO
LEFT REAR DOOR MODULE
CAN B–
CAN B–
CAN B+
CAN B+
INSTRUMENT PANEL
RIGHT REAR DOOR MODULE
CAN B–
CAN B–
CAN B+
CAN B+
HVAC
CELL PHONE MODULE
CAN B–
CAN B–
CAN B+
CAN B+
SEAT HEATERS
MEMORY SEAT MODULE
CAN B–
CAN B–
CAN B+
CAN B+
TIRE PRESSURE MONITOR
?
LEFT FRT. DOOR MODULE
ABS CONTROL MODULE
CAN B–
CAN B–
CAN B+
CAN B+
FREQUENTLY ASKED QUESTION
What Is a Protocol? A protocol is set of rules or a standard used between computers or electronic control modules. Protocols include the type of electrical connectors, voltage levels, and frequency of the transmitted messages. Protocols, therefore, include both the hardware and software needed to communicate between modules.
CLASS B Medium-speed networks, meaning 10,000 to 125,000 bps (10 to 125 Kbs), are generally used for information transfer among modules, such as instrument clusters, temperature sensor data, and other general uses.
CLASS C
High-speed networks, meaning 125,000 to 1,000,000 bps, are generally used for real-time powertrain and vehicle dynamic control. High-speed BUS communication systems now use a controller area network (CAN). SEE FIGURE 49–5.
GENERAL MOTORS COMMUNICATIONS PROTOCOLS UART
General Motors and others use UART communications for some electronic modules or systems. UART is a serial data communications protocol that stands for universal asynchronous receive
C AN AN D N E T W O RK C O M M U N IC A T ION S
527
128 mS
128 mS 1
1
1
1
1
1
1
1 12 V
5V 0V 0
0
0
0
128 mS 0
0
0
0V
0
PIN 8
PIN 1
128 mS PIN 1
PIN 8
PIN 9
PIN 16
PIN 16
PIN 9
UART - PIN 9
FIGURE 49–6 UART serial data master control module is connected to the data link connector at pin 9. and transmit. UART uses a master control module connected to one or more remote modules. The master control module is used to control message traffic on the data line by poling all of the other UART modules. The remote modules send a response message back to the master module. UART uses a fixed pulse-width switching between 0 and 5 V. The UART data BUS operates at a baud rate of 8,192 bps. SEE FIGURE 49–6.
E & C - PIN 14
FIGURE 49–7 The E & C serial data is connected to the data link connector (DLC) at pin 14. CLASS 2 - PIN 2
ENTERTAINMENT AND COMFORT COMMUNICATION The GM entertainment and comfort (E & C) serial data is similar to UART, but uses a 0 to 12 V toggle. Like UART, the E & C serial data uses a master control module connected to other remote modules, which could include the following:
Compact disc (CD) player
Instrument panel (IP) electrical center
Audio system (radio)
Heating, ventilation, and air-conditioning (HVAC) programmer and control head
Steering wheel controls
SEE FIGURE 49–7.
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CHAPTER 4 9
PIN 16
1
0
1
1 7V
0V 0
1
0
1
128 μS
FIGURE 49–8 Class 2 serial data communication is accessible at the data link connector (DLC) at pin 2. KEYWORD 81, 82, AND 2000 PULLED HIGH TO TALK
FIXED PULSE WIDTH
KEYWORD COMMUNICATION
General Motors, like all vehicle manufacturers, must use high-speed serial data to communicate with scan tools on all vehicles effective with the 2008 model year. As mentioned, the standard
PIN 9
0
Class 2 is a serial communications system that operates by toggling between 0 and 7 V at a transfer rate of 10.4 Kbs. Class 2 is used for most high-speed communications between the powertrain control module (PCM) and other control modules, plus to the scan tool. Class 2 is the primary high-speed serial communications system used by GMCAN (CAN). SEE FIGURE 49–8.
GMLAN
PIN 8
64 μS
CLASS 2 COMMUNICATIONS
Keyword 81, 82, and 2000 serial data are also used for some module-to-module communication on GM vehicles. Keyword data BUS signals are toggled from 0 to 12 V when communicating. The voltage or the datastream is zero volts when not communicating. Keyword serial communication is used by the seat heater module and others, but is not connected to the data link connector (DLC). SEE FIGURE 49–9.
PIN 1
1
1
1
1 1
1
12V
0V 0
0
0
0
0
0
FIGURE 49–9 Keyword 82 operates at a rate of 8,192 bps, similar to UART, and keyword 2000 operates at a baud rate of 10,400 bps (the same as a Class 2 communicator). is called controller area network (CAN), which General Motors calls GMLAN, which stands for GM local area network. General Motors uses two versions of GMLAN.
Low-speed GMLAN. The low-speed version is used for driver-controlled functions such as power windows and door locks. The baud rate for low-speed GMLAN is 33,300 bps.
PIN #4 - CHASSIS GROUND
PIN #5 - PCM (SIGNAL L) GROUND
PIN PI N #2 CLAS CL AS SS 2
PIN #6 PI 6 - CAN AN PIIN #1 P #14 - CA CAN +12 V +1
FIGURE 49–10 GMLAN uses pins at terminals 6 and 14.
FIGURE 49–12 A CANdi module will flash the green LED rapidly if communication is detected.
TWISTED PAIR (ONE TWIST PER INCH)
1
DATA LINK CONNECTOR
3
2 4
5
6
VARIABLE CONTROL RELAY MODULE (VCRM)
HIGH VOLTAGE MAGNETIC FIELD
FIGURE 49–11 A twisted pair is used by several different network communications protocols to reduce interference that can be induced in the wiring from nearby electromagnetic sources.
The GMLAN low-speed serial data is not connected directly to the data link connector and uses one wire. The voltage toggles between 0 and 5 V after an initial 12 V spike, which indicates to the modules to turn on or wake up and listen for data on the line. Low-speed GMLAN is also known as single-wire CAN, or SWCAN.
High-speed GMLAN. The baud rate is almost real time at 500 Kbs. This serial data method uses a two-twisted-wire circuit which is connected to the data link connector on pins 6 and 14. SEE FIGURE 49–10.
19
18
DATA ( )
DATA (+)
POWERTRAIN CONTROL MODULE
FIGURE 49–13 A Ford OBD-I diagnostic link connector showing that SCP communication uses terminals in cavities 1 (upper left) and 3 (lower left). A CANdi (CAN diagnostic interface) module is required to be used with the Tech 2 to be able to connect a GM vehicle equipped with GMLAN. SEE FIGURE 49–12.
FORD NETWORK COMMUNICATIONS PROTOCOLS STANDARD CORPORATE PROTOCOL
?
FREQUENTLY ASKED QUESTION
Why Is a Twisted Pair Used? A twisted pair is where two wires are twisted to prevent electromagnetic radiation from affecting the signals passing through the wires. By twisting the two wires about once every inch (9 to 16 times per foot), the interference is canceled by the adjacent wire. SEE FIGURE 49–11.
Only a few Fords had scan tool data accessible through the OBD-I data link connector. To identify an OBD-I (1988–1995) on a Ford vehicle that is equipped with standard corporate protocol (SCP) and be able to communicate through a scan tool, look for terminals in cavities 1 and 3 of the DLC. SEE FIGURE 49–13. SCP uses the J-1850 protocol and is active with the key on. The SCP signal is from 4 V negative to 4.3 V positive, and a scan tool does not have to be connected for the signal to be detected on the terminals. OBD-II (EECV) Ford vehicles use terminals 2 (positive) and 10 (negative) of the 16 pin data link connector (DLC) for network communication, using the SCP module communications.
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2
?
7
FREQUENTLY ASKED QUESTION
What Are U Codes? 10
DATA LINK CONNECTOR
ABS CONTROL MODULE
15
16 SCP BUS (+)
SCP BUS ( )
RESTRAINTS CONTROL MODULE
GENERIC ELECTRONIC MODULE
POWERTRAIN CONTROL MODULE
FIGURE 49–14 A scan tool can be used to check communications with the SCP BUS through terminals 2 and 10 and to the other modules connected to terminal 7 of the data link connector (DLC).
CAN BUS CAN BUS + ABS CONTROL MODULE
DRIVER SEAT MODULE
FEPS UBP CAN 3
6
CAN BUS CAN BUS + POWERTRAIN CONTROL MODULE UBP
14 CAN
The U diagnostic trouble codes were at first “undefined” but are now network-related codes. Use the network codes to help pinpoint the circuit or module that is not working correctly.
CAN BUS CAN BUS + INSTRUMENT CLUSTER
FIGURE 49–15 Many Fords use UBP module communications along with CAN.
The circuit is active without a scan tool command. SEE FIGURE 49–16. The modules on the CCD BUS apply a bias voltage on each wire by using termination resistors. SEE FIGURE 49–17. The difference in voltage between CCD⫹ and CCD⫺ is less than 20 mV. For example, using a digital meter with the black meter lead attached to ground and the red meter lead attached at the data link connector (DLC), a normal reading could include:
Terminal 3 ⫽ 2.45 volts
Terminal 11 ⫽ 2.47 volts
This is an acceptable reading because the readings are 20 mV (0.020 volt) of each other. If both had been exactly 2.5 volts, then this could indicate that the two data lines are shorted together. The module providing the bias voltage is usually the body control module on passenger cars and the front control module on Jeeps and trucks.
PROGRAMMABLE CONTROLLER INTERFACE The Chrysler programmable controller interface (PCI) is a one-wire communication protocol that connects at the OBD-II DLC at terminal 2. The PCI BUS is connected to all modules on the BUS in a star configuration and operates at a baud rate of 10,200 bps. The voltage signal toggles between 7.5 and 0 V. If this voltage is checked at terminal 2 of the OBD-II DLC, a voltage of about 1 V indicates the average voltage and means that the BUS is functioning and is not shorted-to-ground. PCI and CCD are often used in the same vehicle. SEE FIGURE 49–18. SERIAL COMMUNICATIONS INTERFACE
UART-BASED PROTOCOL Newer Fords use the CAN for scan tool diagnosis, but still retain SCP and UART-based protocol (UBP) for some modules. SEE FIGURES 49–14 AND 49–15.
CHRYSLER COMMUNICATIONS PROTOCOLS
Chrysler used serial communications interface (SCI) for most scan tool and flash reprogramming functions until it was replaced with CAN. SCI is connected at the OBD-II diagnostic link connector (DLC) at terminals 6 (SCI receive) and 7 (SCI transmit). A scan tool must be connected to test the circuit.
CONTROLLER AREA NETWORK
CCD
Since the late 1980s, the Chrysler Collision Detection (CCD) multiplex network is used for scan tool and module communications. It is a differential-type communication and uses a twisted pair of wires. The modules connected to the network apply a bias voltage on each wire. CCD signals are divided into plus and minus (CCD⫹ and CCD⫺) and the voltage difference does not exceed 0.02 V. The baud rate is 7,812.5 bps.
BACKGROUND Robert Bosch Corporation developed the CAN protocol, which was called CAN 1.2, in 1993. The CAN protocol was approved by the Environmental Protection Agency (EPA) for 2003 and newer vehicle diagnostics, and a legal requirement for all vehicles by 2008. The CAN diagnostic systems use pins 6 and 14 in the standard 16 pin OBD-II (J-1962) connector. Before CAN, the scan tool protocol had been manufacturer specific.
NOTE: The “collision” in the Chrysler Collision detection BUS communications refers to the program that avoids conflicts of information exchange within the BUS, and does not refer to airbags or other accident-related circuits of the vehicle.
CAN FEATURES
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The CAN protocol offers the following features.
Faster than other BUS communication protocols
Cost effective because it is an easier system than others to use
JOINT CONN. 3 CCD BUS (+)
11
3
CCD BUS ( )
16
POWERTRAIN CONTROL MODULE
INSTRUMENT CCD (+) CLUSTER CCD ( ) CCD (+) RADIO
CCD ( )
CCD BUS ( )
CCD BUS (+)
B+
CCD (+)
CENTRAL TIMER MODULE
CCD ( )
AIR BAG CONTROL CCD (+) MODULE CCD ( ) CCD (+)
OVERHEAD CONSOLE
CCD ( )
FIGURE 49–16 CCD signals are labeled plus and minus and use a twisted pair of wires. Notice that terminals 3 and 11 of the data link connector are used to access the CCD BUS from a scan tool. Pin 16 is used to supply 12 volts to the scan tool. ANTI-LOCK BRAKES CCD (+)
5V
CCD( )
13K Ω 2.39 V
RADIO CCD (+)
BUS (+)
CCD( ) 120 Ω 2.51 V
2
6
VEHICLE THEFT CCD (+)
BUS (–)
CCD( ) DATA LINK CONNECTOR
13K Ω
CCD( )
No wakeup needed because it is a two-wire system
Supports up to15 modules plus a scan tool
Uses a 120 ohm resistor at the ends of each pair to reduce electrical noise
Applies 2.5 volts on both wires: H (high) goes to 3.5 volts when active
POWERTRAIN CONTROL MODULE
FIGURE 49–18 Many Chrysler vehicles use both SCI and CCD for module communication.
all be linked using a gateway within the same vehicle. The gateway is usually one of the many modules in the vehicle.
CAN A. This class operates on only one wire at slow speeds and is therefore less expensive to build. CAN A operates a data transfer rate of 33.33 Kbs in normal mode and up to 83.33 Kbs during reprogramming mode. CAN A uses the vehicle ground as the signal return circuit.
CAN B. This class operates on a two-wire network and does not use the vehicle ground as the signal return circuit. CAN B
L (low) goes to 1.5 volts when active
SEE FIGURE 49–19.
CAN CLASS A, B, AND C
There are three classes of CAN and they operate at different speeds. The CAN A, B, and C networks can
CCD( )
Message based rather than address based which makes it easier to expand
CCD (+)
SCI TRANSMIT
Less effected by electromagnetic interference (Data is transferred on two wires that are twisted together, called twisted pair, to help reduce EMI interference.)
26
46
SCI RECEIVE
FIGURE 49–17 The differential voltage for the CCD BUS is created by using resistors in a module.
ATC MODULE CCD (+)
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FIGURE 49–19 CAN uses a differential type of module communication where the voltage on one wire is the equal but opposite voltage on the other wire. When no communication is occurring, both wires have 2.5 volts applied. When communication is occurring, CAN H (high) goes up 1 volt to 3.5 volts and CAN L (low) goes down 1 volt to 1.5 volts.
VOLTAGE CAN H
3.5 V
(3.5 V)
2.5 V
CAN L 1.5 V (1.5 V)
INACTIVE (RECESSIVE)
ACTIVE (DOMINANT)
FIGURE 49–20 A typical (generic) system showing how the CAN BUS is connected to various electrical accessories and systems in the vehicle.
TIME
CAN BUS (+) CAN BUS ( ) 14
6
TRANSPONDER KEY
INSTRUMENT CCD (+) CLUSTER CCD ( ) CCD (+) NODE 3
uses a data transfer rate of 95.2 Kbs. Instead, CAN B (and CAN C) uses two network wires for differential signaling. This means that the two data signal voltages are opposite to each other and used for error detection by constantly being compared. In this case, when the signal voltage at one of the CAN data wires goes high (CAN H), the other one goes low (CAN L), hence the name differential signaling. Differential signaling is also used for redundancy, in case one of the signal wires shorts out.
CAN C. This class is the highest speed CAN protocol with speeds up to 500 Kbs. Beginning with 2008 models, all vehicles sold in the United States must use CAN BUS for scan tool communications. Most vehicle manufacturers started using CAN in older models; and it is easy to determine if a vehicle is equipped with CAN. The CAN BUS communicates to the scan tool through terminals 6 and 14 of the DLC indicating that the vehicle is equipped with CAN. SEE FIGURE 49–20.
The total voltage remains constant at all times and the electromagnetic field effects of the two data BUS lines cancel each other out. The data BUS line is protected against received radiation and is virtually neutral in sending radiation.
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CCD ( )
CAN BUS ( )
IMMOBILIZER MODULE
B+
CAN BUS (+)
16
CCD (+) NODE 4
CCD ( ) CCD (+)
NODE 5
CCD ( )
HONDA/TOYOTA COMMUNICATIONS The primary BUS communications on pre-CAN-equipped vehicles is ISO 9141-2 using terminals 7 and 15 at the OBD-II DLC. SEE FIGURE 49–21. A factory scan tool or an aftermarket scan tool equipped with enhanced original equipment (OE) software is needed to access many of the BUS messages. SEE FIGURE 49–22.
EUROPEAN BUS COMMUNICATIONS UNIQUE DIAGNOSTIC CONNECTOR Many different types of module communications protocols are used on European vehicles such as Mercedes and BMW.
4
10
5
7
14
16
FIGURE 49–21 A DLC from a pre-CAN Acura. It shows terminals in cavities 4, 5 (grounds), 7, 10, 14, and 16 (B⫹).
FIGURE 49–23 A typical 38-cavity diagnostic connector as found on many BMW and Mercedes vehicles under the hood. The use of a breakout box (BOB) connected to this connector can often be used to gain access to module BUS information.
FIGURE 49–22 A Honda scan display showing a B and two U codes, all indicating a BUS-related problem(s). Most of these communication BUS messages cannot be accessed through the data link connector (DLC). To check the operation of the individual modules, a scan tool equipped with factory-type software will be needed to communicate with the module through the gateway module. SEE FIGURE 49–23 for an alternative access method to the modules.
MEDIA ORIENTED SYSTEM TRANSPORT BUS
The media oriented system transport (MOST) BUS uses fiber optics for moduleto-module communications in a ring or star configuration. This BUS system is currently being used for entertainment equipment data communications for videos, CDs, and other media systems in the vehicle.
FIGURE 49–24 A breakout box (BOB) used to access the BUS terminals while using a scan tool to activate the modules. This breakout box is equipped with LEDs that light when circuits are active.
?
FREQUENTLY ASKED QUESTION
How Do You Know What System Is Used? Use service information to determine which network communication protocol is used. However, due to the various systems on some vehicles, it may be easier to look at the data link connection to determine the system. All OBD-II vehicles have terminals in the following cavities. Terminal 4: chassis ground
MOTOROLA INTERCONNECT BUS Motorola interconnect (MI) is a single-wire serial communications protocol, using one master control module and many slave modules. Typical application of the MI BUS protocol is with power and memory mirrors, seats, windows, and headlight levelers. DISTRIBUTED SYSTEM INTERFACE BUS Distributed system interface (DSI) BUS protocol was developed by Motorola and uses a two-wire serial BUS. This BUS protocol is currently being used for safety-related sensors and components.
Terminal 5: computer (signal) ground Terminal 16: 12 V positive The terminals in cavities 6 and 14 mean that this vehicle is equipped with CAN as the only module communication protocol available at the DLC. To perform a test of the BUS, use a breakout box (BOB) to gain access to the terminals while connecting to the vehicle, using a scan tool. SEE FIGURE 49–24 for a typical OBD-II connector breakout box.
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Class 2 Message Monitor Status
Modules BCM/BFC/DIM/SBM/TBC PCM/VCM ABS/TCS IPC SIR Radio ACM/HCM
Active Active Active Active Active Active Active 00:00:03 1 / 9
1 1 1 1 1 1 1
BCM/BFC/DIM/SBM/TBC Sleep Mode
FIGURE 49–25 This Honda scan tool allows the technician to turn on individual lights and operate individual power windows and other accessories that are connected to the BUS system.
• Ping modules. Start the Class 2 diagnosis by using a scan tool and select diagnostic circuit check. If no diagnostic trouble codes (DTCs) are shown, there could be a communication problem. Select message monitor, which will display the status of all of the modules on the Class 2 BUS circuit. The modules that are awake will be shown as active and the scan tool can be used to ping individual modules or command all modules. The ping command should change the status from “active” to “inactive.” SEE FIGURE 49–26.
The Bosch-Siemans-Temic (BST) BUS is another system that is used for safety-related components and sensors in a vehicle, such as airbags. The BST BUS is a two-wire system and operates up to 250,000 bps.
BYTEFLIGHT BUS The byteflight BUS is used in safety critical systems, such as airbags, and uses the time division multiple access (TDMA) protocol, which operates at 10 million bps using a plastic optical fiber (POF). FLEXRAY BUS FlexRay BUS is a version of byteflight, and is a high-speed serial communication system for in-vehicle networks. FlexRay is commonly used for steer-by-wire and brake-by-wire systems.
NOTE: If an excessive parasitic draw is being diagnosed, use a scan tool to ping the modules in one way to determine if one of the modules is not going to sleep and causing the excessive battery drain. • Check state of health. All modules on the Class 2 BUS circuit have at least one other module responsible for reporting state of health (SOH). If a module fails to send a state of health message within five seconds, the companion module will set a diagnostic trouble code for the module that did not respond. The defective module is not capable of sending this message.
DOMESTIC DIGITAL BUS
The domestic digital BUS, commonly designated D2B, is an optical BUS system connecting audio, video, computer, and telephone components in a single-ring structure with a speed of up to 5,600,000 bps.
STEP 3
Check the resistance of the terminating resistors. Most high-speed BUS systems use resistors at each end, called terminating resistors. These resistors are used to help reduce interference into other systems in the vehicle. Usually two 120 ohm resistors are installed at each end and are therefore connected electrically in parallel. Two 120 ohm resistors connected in parallel would measure 60 ohms if being tested using an ohmmeter. SEE FIGURE 49–27.
STEP 4
Check data BUS for voltages. Use a digital multimeter set to DC volts, to monitor communications and check the BUS for proper operation. Some BUS conditions and possible causes include: • Signal is zero volt all of the time. Check for short-toground by unplugging modules one at a time to check if one module is causing the problem. • Signal is high or 12 volts all of the time. The BUS circuit could be shorted to 12 V. Check with the customer to see if any service or body repair work was done recently. Try unplugging each module one at a time to pin down which module is causing the communications problem.
NETWORK COMMUNICATIONS DIAGNOSIS STEPS TO FINDING A FAULT When a network communications fault is suspected, perform the following steps. STEP 1
Check everything that does and does not work. Often accessories that do not seem to be connected can help identify which module or BUS circuit is at fault.
STEP 2
Perform module status test. Use a factory level scan tool or an aftermarket scan tool equipped with enhanced software that allows OE-like functions. Check if the components or systems can be operated through the scan tool. SEE FIGURE 49–25.
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Ping All Modules
FIGURE 49–26 Modules used in a General Motors vehicle can be “pinged” using a Tech 2 scan tool.
BOSCH-SIEMANS-TEMIC BUS
LOCAL INTERCONNECT NETWORK BUS Local interconnect network (LIN) is a BUS protocol used between intelligent sensors and actuators, and has a BUS speed of 19,200 bps.
Ping Module
OHMMETER
TECH TIP DIGITAL MULTIMETER RECORD
MAX MIN
60
% HZ
0 1 2 3 4 5 6 7 8
9 0
MIN MAX
No Communication? Try Bypass Mode.
HZ
mV mA A
V
A
If a Tech 2 scan tool shows “no communication,” try using the bypass mode to see what should be on the data display. To enter bypass mode, perform the following steps.
A
V
mA A
COM
V
14
6
120
BCM
STEP 1
Select tool option (F3).
STEP 2
Set communications to bypass (F5).
STEP 3
Select enable.
STEP 4
Input make/model and year of vehicle.
STEP 5
Note all parameters that should be included, as shown. The values will not be shown.
PCM TERMINATOR 120 VCIM
TERMINATOR
REAL WORLD FIX The Radio Caused No-Start Story
PSCM VCIM
FIGURE 49–27 Checking the terminating resistors using an ohmmeter at the DLC.
A 2005 Chevrolet Cobalt did not start. A technician checked with a subscription-based helpline service and discovered that a fault with the Class 2 data circuit could prevent the engine from starting. The advisor suggested that a module should be disconnected one at a time to see if one of them was taking the data line to ground. The two most common components on the Class 2 serial data line that have been known to cause a lack of communication and become shorted-to-ground are the radio and electronic brake control module (EBCM). The first one the technician disconnected was the radio. The engine started and ran. Apparently the Class 2 serial data line was shorted-to-ground inside the radio, which took the entire BUS down. When BUS communication is lost, the PCM is not able to energize the fuel pump, ignition, or fuel injectors so the engine would not start. The radio was replaced to solve the no-start condition.
?
FREQUENTLY ASKED QUESTION
Which Module Is the Gateway Module?
FIGURE 49–28 Use front-probe terminals to access the data link connector. Always follow the specified back-probe and front-probe procedures as found in service information. • A variable voltage usually indicates that messages are being sent and received. CAN and Class 2 can be identified by looking at the data link connector (DLC) for a terminal in cavity number 2. Class 2 is active all of the time the ignition is on, and therefore voltage variation between 0 and 7 V can be measured using a DMM set to read DC volts. SEE FIGURE 49–28. STEP 5
Use a digital storage oscilloscope to monitor the waveforms of the BUS circuit. Using a scope on the data line terminals can show if communication is being transmitted. Typical faults and their causes include: • Normal operation. Normal operation shows variable voltage signals on the data lines. It is impossible to know what information is being transmitted, but if there is activity with
The gateway module is responsible for communicating with other modules and acts as the main communications module for scan tool data. Most General Motors vehicles use the body control module (BCM) or the instrument panel control (IPC) module as the gateway. To verify which module is the gateway, check the schematic and look for one that has voltage applied during all of the following conditions. • Key on, engine off • Engine cranking • Engine running
short sections of inactivity, this indicates normal data line transmission activity. SEE FIGURE 49–29. • High voltage. If there is a constant high-voltage signal without any change, this indicates that the data line is shorted to voltage. • Zero or low voltage. If the data line voltage is zero or almost zero and not showing any higher voltage signals, then the data line is short-to-ground.
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HIGH
LOW
CAN BUS LOOKS GOOD CAN LOW
CAN HIGH
FIGURE 49–29 (a) Data is sent in packets, so it is normal to see activity then a flat line between messages. (b) A CAN BUS should show voltages that are opposite when there is normal communications. CAN H (high) circuit should go from 2.5 volts at rest to 3.5 volts when active. The CAN L (low) circuit goes from 2.5 volts at rest to 1.5 volts when active. STEP 6
Follow factory service information instructions to isolate the cause of the fault. This step often involves disconnecting one module at a time to see if it is the cause of a short-to-ground or an open in the BUS circuit.
PIN NO. ASSIGNMENTS
1 2 3 4 5 6 7 8
OBD-II DATA LINK CONNECTOR
9 10 11 12 13 14 15 16 OBD-II DLC
All OBD-II vehicles use a 16 pin connector that includes: Pin 4 ⫽ chassis ground Pin 5 ⫽ signal ground Pin 16 ⫽ battery power (4 A max)
SEE FIGURE 49–30.
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16.
MANUFACTURER'S DISCRETION BUS + LINE, SAE J1850 MANUFACTURER'S DISCRETION CHASSIS GROUND SIGNAL GROUND MANUFACTURER'S DISCRETION K LINE, ISO 9141 MANUFACTURER'S DISCRETION MANUFACTURER'S DISCRETION BUS – LINE, SAE J1850 MANUFACTURER'S DISCRETION MANUFACTURER'S DISCRETION MANUFACTURER'S DISCRETION MANUFACTURER'S DISCRETION L LINE, ISO 9141 VEHICLE BATTERY POSITIVE (4A MAX)
FIGURE 49–30 A 16 pin OBD-II DLC with terminals identified. Scan tools use the power pin (16) and ground pin (4) for power so that a separate cigarette lighter plug is not necessary on OBD-II vehicles.
GENERAL MOTORS VEHICLES
SAE J-1850 (VPW, Class 2, 10.4 Kbs) standard, which uses pins 2, 4, 5, and 16, but not 10
GM Domestic OBD-II Pin 1 and 9: CCM (comprehensive component monitor) slow baud rate, 8,192 UART
ASIAN, CHRYSLER, AND EUROPEAN VEHICLES
ISO 9141-2 standard, which uses pins 4, 5, 7, 15, and 16
Chrysler Domestic Group OBD-II
Pins 2 and 10: OEM enhanced, fast rate, 40,500 baud rate
Pins 2 and 10: CCM
Pins 7 and 15: generic OBD-II, ISO 9141, 10,400 baud rate
Pins 3 and 14: OEM enhanced, 60,500 baud rate
Pins 6 and 14: GMLAN
Pins 7 and 15: generic OBD-II, ISO 9141, 10,400 baud rate
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CHAPTER 4 9
HVAC CONTROL MODULE INSTRUMENT PANEL CLUSTER (4) DOOR MODULES
LOW SPEED GMLAN
BODY CONTROL MODULE (BCM) GATEWAY
CLASS 2
SENSING DIAGNOSTIC MODULE (SDM)
2
RADIO
HIGH SPEED GMLAN
VCI MODULE
NAVIGATION RADIO
ELECTRONIC BRAKE/ TRACTION CONTROL (EBTCM)
VEHICLE COMMUNICATIONS INTERFACE MODULE (VCIM)
6
14
MEMORY SEAT MODULE
TRANSMISSION CONTROL MODULE (TCM)
POWERTRAIN CONTROL MODULE (ECM)
HEADS UP DISPLAY (HUD)
UART DATA 2
UART DATA 1
THROTTLE ACTUATOR
FIGURE 49–31 This schematic of a Chevrolet Equinox shows that the vehicle uses a GMLAN BUS (DLC pins 6 and 14), plus a Class 2 (pin 2) and UART.
TECH TIP
FORD VEHICLES
SAE J-1850 (PWM, 41.6 Kbs) standard, which uses pins 2, 4, 5, 10, and 16
Ford Domestic OBD-II
Check Computer Data Line Circuit Schematic Many General Motors vehicles use more than one type of BUS communications protocol. Check service information (SI) and look at the schematic for computer data line circuits which should show all of the data BUSes and their connectors to the diagnostic link connector (DLC). SEE
Pins 2 and 10: CCM Pins 6 and 14: OEM enhanced, Class C, 40,500 baud rate Pins 7 and 15: generic OBD-II, ISO 9141, 10,400 baud rate
FIGURE 49–31.
REVIEW QUESTIONS 1. Why is a communication network used?
3. Why is a gateway module used?
2. Why are the two wires twisted if used for network communications?
4. What are U codes?
CHAPTER QUIZ 3. A high-speed CAN BUS communicates with a scan tool through which terminal(s)? a. 6 and 14 c. 7 and 15 b. 2 d. 4 and 16
1. Technician A says that module communications networks are used to reduce the number of wires in a vehicle. Technician B says that a communications network is used to share data from sensors, which can be used by many different modules. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
4. UART uses a ______________ signal that toggles 0 V. a. 5 V c. 8 V b. 7 V d. 12 V
2. A module is also known as a ______________. a. BUS c. Terminator b. Node d. Resistor pack
5. GM Class 2 communication toggles between ______________. a. 5 and 7 V c. 7 and 12 V b. 0 and 12 V d. 0 and 7 V
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537
6. Which terminal of the data link connector does General Motors use for Class 2 communication? a. 1 c. 3 b. 2 d. 4 7. GMLAN is the General Motors term for which type of module communication? a. UART c. High-speed CAN b. Class 2 d. Keyword 2000 8. CAN H and CAN L operate how? a. CAN H is at 2.5 volts when not transmitting. b. CAN L is at 2.5 volts when not transmitting. c. CAN H goes to 3.5 volts when transmitting. d. All of the above
chapter
9. Which terminal of the OBD-II data link connector is the signal ground for all vehicles? a. 1 b. 3 c. 4 d. 5 10. Terminal 16 of the OBD-II data link connector is used for what? a. Chassis ground b. 12 V positive c. Module (signal ground) d. Manufacturer’s discretion
BATTERIES
50 OBJECTIVES: After studying Chapter 50, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “B” (Battery Diagnosis and Service). • Describe how a battery works. • List battery ratings. • Describe deep cycling. • Discuss how charge indicators work. KEY TERMS: AGM 542 • Ampere hour 543 • Battery Council International (BCI) 543 • CA 543 • CCA 543 • Cells 539 • Deep cycling 543 • Electrolyte 540 • Element 539 • Flooded cell batteries 542 • Gassing 539 • Gel battery 542 • Grid 538 • Low-water-loss batteries 538 • Maintenance-free battery 538 • MCA 543 • Partitions 539 • Porous lead 539 • Recombinant battery 542 • Reserve capacity 543 • Sediment chamber 538 • SLA 542 • SLI 539 • Specific gravity 540 • Sponge lead 539 • SVR 542 • VRLA 542
INTRODUCTION PURPOSE AND FUNCTION Everything electrical in a vehicle is supplied current from the battery. The battery is one of the most important parts of a vehicle because it is the heart or foundation of the electrical system. The primary purpose of an automotive battery is to provide a source of electrical power for starting and for electrical demands that exceed alternator output. WHY BATTERIES ARE IMPORTANT
The battery also acts as a stabilizer to the voltage for the entire electrical system. The battery is a voltage stabilizer because it acts as a reservoir where large amounts of current (amperes) can be removed quickly during starting and replaced gradually by the alternator during charging.
The battery must be in good (serviceable) condition before the charging system and the cranking system can be tested. For example, if a battery is discharged, the cranking circuit (starter motor) could test as being defective because the battery voltage might drop below specifications. The charging circuit could also test as being defective because of a weak or discharged battery. It is important to
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test the vehicle battery before further testing of the cranking or charging system.
BATTERY CONSTRUCTION CASE
Most automotive battery cases (container or covers) are constructed of polypropylene, a thin (approximately 0.08 in., or 0.02 mm, thick), strong, and lightweight plastic. In contrast, containers for industrial batteries and some truck batteries are constructed of a hard, thick rubber material. Inside the case are six cells (for a 12 volt battery). SEE FIGURE 50–1. Each cell has positive and negative plates. Built into the bottom of many batteries are ribs that support the lead-alloy plates and provide a space for sediment to settle, called the sediment chamber. This space prevents spent active material from causing a short circuit between the plates at the bottom of the battery. A maintenance-free battery uses little water during normal service because of the alloy material used to construct the battery plate grids. Maintenance-free batteries are also called low-water-loss batteries.
GRIDS
Each positive and negative plate in a battery is constructed on a framework, or grid, made primarily of lead. Lead is a
?
FREQUENTLY ASKED QUESTION
What Is an SLI Battery?
PLASTIC CASE
Sometimes the term SLI is used to describe a type of battery. SLI means starting, lighting, and ignition, and describes the use of a typical automotive battery. Other types of batteries used in industry are usually batteries designed to be deep cycled and are usually not as suitable for automotive needs.
NEGATIVE PLATES POSITIVE PLATES
Low-maintenance batteries use a low percentage of antimony (about 2% to 3%), or use antimony only in the positive grids and calcium for the negative grids. The percentages that make up the alloy of the plate grids constitute the major difference between standard and maintenance-free batteries. The chemical reactions that occur inside each battery are identical regardless of the type of material used to construct the grid plates.
POSITIVE PLATES
The positive plates have lead dioxide (peroxides), in paste form placed onto the grid framework. This process is called pasting. This active material can react with the sulfuric acid of the battery and is dark brown in color.
SEPARATORS
FIGURE 50–1 Batteries are constructed of plates grouped into cells and installed in a plastic case.
FIGURE 50–2 A grid from a battery used in both positive and negative plates. soft material and must be strengthened for use in an automotive battery grid. Adding antimony or calcium to the pure lead adds strength to the lead grids. SEE FIGURE 50–2. Battery grids hold the active material and provide the electrical pathways for the current created in the plate. Maintenance-free batteries use calcium instead of antimony, because 0.2% calcium has the same strength as 6% antimony. A typical lead-calcium grid uses only 0.09% to 0.12% calcium. Using low amounts of calcium instead of higher amounts of antimony reduces gassing. Gassing is the release of hydrogen and oxygen from the battery that occurs during charging and results in water usage.
NEGATIVE PLATES The negative plates are pasted to the grid with a pure porous lead, called sponge lead, and are gray in color. SEPARATORS The positive and the negative plates must be installed alternately next to each other without touching. Nonconducting separators are used, which allow room for the reaction of the acid with both plate materials, yet insulate the plates to prevent shorts. These separators are porous (with many small holes) and have ribs facing the positive plate. Separators can be made from resin-coated paper, porous rubber, fiberglass, or expanded plastic. Many batteries use envelope-type separators that encase the entire plate and help prevent any material that may shed from the plates from causing a short circuit between plates at the bottom of the battery. CELLS Cells are constructed of positive and negative plates with insulating separators between each plate. Most batteries use one more negative plate than positive plate in each cell; however, many newer batteries use the same number of positive and negative plates. A cell is also called an element. Each cell is actually a 2.1 volt battery, regardless of the number of positive or negative plates used. The greater the number of plates used in each cell, the greater the amount of current that can be produced. Typical batteries contain four positive plates and five negative plates per cell. A 12 volt battery contains six cells connected in series, which produce 12.6 volts (6 ⫻ 2.1 ⫽ 12.6) and contain 54 plates (9 plates per cell ⫻ 6 cells). If the same 12 volt battery had five positive plates and six negative plates, for a total of 11 plates per cell (5 ⫹ 6), or 66 plates (11 plates ⫻ 6 cells), then it would have the same voltage, but the amount of current that the battery could produce would be increased. SEE FIGURE 50–3. The amperage capacity of a battery is determined by the amount of active plate material in the battery and the area of the plate material exposed to the electrolyte in the battery. PARTITIONS Each cell is separated from the other cells by partitions, which are made of the same material as that used for the outside case of the battery. Electrical connections between cells are provided by lead connectors that loop over the top of the partition and connect the plates of the cells together. Many batteries connect the
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S ⫽ Symbol for sulfur O4 ⫽ Symbol for oxygen (the subscript 4 indicates that there are four atoms of oxygen) Electrolyte is sold premixed in the proper proportion and is factory installed or added to the battery when the battery is sold. Additional electrolyte must never be added to any battery after the original electrolyte fill. It is normal for some water (H2O) in the form of hydrogen and oxygen gases to escape during charging as a result of the chemical reactions. The escape of gases from a battery during charging or discharging is called gassing. Only pure distilled water should be added to a battery. If distilled water is not available, clean drinking water can be used.
HOW A BATTERY WORKS PRINCIPLE INVOLVED The principle of how a battery works is based on a scientific principle discovered years ago that states: FIGURE 50–3 Two groups of plates are combined to form a battery element.
When two dissimilar metals are placed in an acid, electrons flow between the metals if a circuit is connected between them.
This can be demonstrated by pushing a steel nail and a piece of solid copper wire into a lemon. Connect a voltmeter to the ends of the copper wire and nail, and voltage will be displayed.
A fully charged lead-acid battery has a positive plate of lead dioxide (peroxide) and a negative plate of lead surrounded by a sulfuric acid solution (electrolyte). The difference in potential (voltage) between lead peroxide and lead in acid is approximately 2.1 volts.
DURING DISCHARGING The positive plate lead dioxide (PbO2) combines with the SO4, forming PbSO4 from the electrolyte and releases its O2 into the electrolyte, forming H2O. The negative plate also combines with the SO4 from the electrolyte and becomes lead sulfate (PbSO4). SEE FIGURE 50–5. FULLY DISCHARGED STATE When the battery is fully discharged, both the positive and the negative plates are PbSO4 (lead sulfate) and the electrolyte has become water (H2O). As the battery is being discharged, the plates and electrolyte approach the completely discharged state. There is also the danger of freezing when a battery is discharged, because the electrolyte is mostly water. CAUTION: Never charge or jump start a frozen battery because the hydrogen gas can get trapped in the ice and ignite if a spark is caused during the charging process. The result can be an explosion.
DURING CHARGING
FIGURE 50–4 A cutaway battery showing the connection of the cells to each other through the partition. cells directly through the partition connectors, which provide the shortest path for the current and the lowest resistance. SEE FIGURE 50–4.
During charging, the sulfate from the acid leaves both the positive and the negative plates and returns to the electrolyte, where it becomes normal-strength sulfuric acid solution. The positive plate returns to lead dioxide (PbO2), the negative plate is again pure lead (Pb), and the electrolyte becomes H2SO4. SEE FIGURE 50–6.
ELECTROLYTE
Electrolyte is the term used to describe the acid solution in a battery. The electrolyte used in automotive batteries is a solution (liquid combination) of 36% sulfuric acid and 64% water. This electrolyte is used for both lead-antimony and leadcalcium (maintenance-free) batteries. The chemical symbol for this sulfuric acid solution is H2SO4. H2 ⫽ Symbol for hydrogen (the subscript 2 means that there are two atoms of hydrogen)
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SPECIFIC GRAVITY DEFINITION The amount of sulfate in the electrolyte is determined by the electrolyte’s specific gravity, which is the ratio of the weight of a given volume of a liquid to the weight of an equal volume of water. In other words, the more dense the liquid is, the higher its
ELECTRICAL LOAD
SPECIFIC GRAVITY 1.260 - 80
–
ELECTROLYTE Pb
O2
H2
SO4
H2
SO4
POSITIVE PLATE (PbO2)
PLATES
PLATES
+
SPECIFIC GRAVITY BELOW 1.230 - 50
Pb
FULLY CHARGED
NEGATIVE PLATE (Pb)
SPECIFIC GRAVITY 1.200 - 20
GOING DOWN
SPECIFIC GRAVITY 1.140 - 60
FIGURE 50–5 Chemical reaction for a lead-acid battery that is fully charged being discharged by the attached electrical load. CHARGING SYSTEM
+
– UNSAFE!
Pb
SO4
H2
H2
POSITIVE PLATE
O
Pb
SO4
ACID
DISCHARGED
WATER
FIGURE 50–7 As the battery becomes discharged, the specific gravity of the battery acid decreases.
O
NEGATIVE PLATE
FIGURE 50–6 Chemical reaction for a lead-acid battery that is fully discharged being charged by the attached generator.
?
FREQUENTLY ASKED QUESTION
Is There an Easy Way to Remember How a Battery Works? Yes. Think of the sulfuric acid solution in the electrolyte being deposited, then removed from the plates. • During discharge. The acid (SO4) is leaving the electrolyte and getting onto both plates. • During charging. The acid (SO4) is being forced from both plates and enters the electrolyte.
specific gravity. Pure water is the basis for this measurement and is given a specific gravity of 1.000 at 80°F (27°C). Pure sulfuric acid has a specific gravity of 1.835; the correct concentration of water and sulfuric acid (called electrolyte—64% water, 36% acid) is 1.260 to 1.280 at 80°F. The higher the battery’s specific gravity, the more fully it is charged. SEE FIGURE 50–7.
CHARGE INDICATORS Some batteries are equipped with a built-in state-of-charge indicator, commonly called green eyes. This
FIGURE 50–8 Typical battery charge indicator. If the specific gravity is low (battery discharged), the ball drops away from the reflective prism. When the battery is charged enough, the ball floats and reflects the color of the ball (usually green) back up through the sight glass and the sight glass is dark.
indicator is simply a small, ball-type hydrometer that is installed in one cell. This hydrometer uses a plastic ball that floats if the electrolyte density is sufficient (which it is when the battery is about 65% charged). When the ball floats, it appears in the hydrometer’s sight glass, changing its color. SEE FIGURE 50–8. Because the hydrometer is only testing one cell (out of six on a 12 volt battery), and because the hydrometer ball can easily stick
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SPECIFIC GRAVITY
STATE OF CHARGE
BATTERY VOLTAGE (V)
1.265
Fully charged
12.6 or higher
1.225
75% charged
12.4
1.190
50% charged
12.2
1.155
25% charged
12.0
Lower than 1.120
Discharged
11.9 or lower
CHART 50–1 A comparison showing the relationship among specific gravity, battery voltage, and state of charge. in one position, do not trust that this is accurate information about a state of charge (SOC) of the battery. Values of specific gravity, state of charge, and battery voltage at 80°F (27°C) are given in CHART 50–1.
VALVE REGULATED LEAD-ACID BATTERIES TERMINOLOGY
There are two basic types of valve regulated lead-acid (VRLA), also called sealed valve-regulated (SVR) or sealed lead-acid (SLA), batteries. These batteries use a low-pressure venting system that releases excess gas and automatically reseals if a buildup of gas is created due to overcharging. The two types include the following:
Absorbed glass mat. The acid used in an absorbed glass mat (AGM) battery is totally absorbed into the separator, making the battery leakproof and spillproof. The battery is assembled by compressing the cell about 20%, then inserting it into the container. The compressed cell helps reduce damage caused by vibration and helps keep the acid tightly against the plates. The sealed maintenance-free design uses a pressure release valve in each cell. Unlike conventional batteries that use a liquid electrolyte, called flooded cell batteries, most of the hydrogen and oxygen given off during charging remains inside the battery. The separator or mat is only 90% to 95% saturated with electrolyte, thereby allowing a portion of the mat to be filled with gas. The gas spaces provide channels to allow the hydrogen and oxygen gases to recombine rapidly and safely. Because the acid is totally absorbed into the glass mat separator, an AGM battery can be mounted in any direction. AGM batteries also have a longer service life, often lasting 7 to 10 years. Absorbed glass mat batteries are used as standard equipment in some vehicles such as the Chevrolet Corvette and in most Toyota hybrid electric vehicles. SEE FIGURE 50–9. Gelled electrolyte batteries. In a gelled electrolyte battery, silica is added to the electrolyte, which turns the electrolyte into a substance similar to gelatin. This type of battery is also called a gel battery.
Both types of valve-regulated, lead-acid batteries are also called recombinant battery design. A recombinant-type battery means that the oxygen gas generated at the positive plate travels through the dense electrolyte to the negative plate. When the oxygen reaches the negative plate, it reacts with the lead, which consumes the oxygen gas and prevents the formation of hydrogen gas. It is because of this oxygen recombination that VRLA batteries do not use water.
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FIGURE 50–9 An absorbed glass mat battery is totally sealed and is more vibration resistant than conventional lead-acid batteries.
CAUSES AND TYPES OF BATTERY FAILURE NORMAL LIFE
Most automotive batteries have a useful service life of three to seven years; however, proper care can help increase the life of a battery, but abuse can shorten it. The major cause of premature battery failure is overcharging.
CHARGING VOLTAGE The automotive charging circuit, consisting of an alternator and connecting wires, must be operating correctly to prevent damage to the battery.
Charging voltages higher than 15.5 volts can damage a battery by warping the plates as a result of the heat of overcharging.
AGM batteries can be damaged if charged at a voltage higher than 14.5 volts.
Overcharging also causes the active plate material to disintegrate and fall out of the supporting grid framework. Vibration or bumping can also cause internal damage similar to that caused by overcharging. It is important, therefore, to ensure that all automotive batteries are securely clamped down in the vehicle. The shorting of cell plates can occur without notice. If one of the six cells of a 12 volt battery is shorted, the resulting voltage of the battery is only 10 volts (12 ⫺ 2 ⫽ 10). With only 10 volts available, the starter usually will not be able to start the engine.
BATTERY HOLD-DOWNS
All batteries must be attached securely to the vehicle to prevent battery damage. Normal vehicle vibrations can cause the active materials inside the battery to shed. Battery hold-down clamps or brackets help reduce vibration, which can greatly reduce the capacity and life of any battery. SEE FIGURE 50–10.
BATTERY RATINGS Batteries are rated according to the amount of current they can produce under specific conditions.
COLD-CRANKING AMPERES Every automotive battery must be able to supply electrical power to crank the engine in cold weather and still provide battery voltage high enough to operate the ignition
BATTERY HOLD DOWN BRACKET
FIGURE 50–10 A typical battery hold-down bracket. All batteries should use a bracket to prevent battery damage due to vibration and shock.
?
FIGURE 50–11 This battery has a cranking amperes (CA) rating of 1,000. This means that this battery is capable of cranking an engine for 30 seconds at a temperature of 32°F (0°C) at a minimum of 1.2 volts per cell (7.2 volts for a 12 volt battery).
?
FREQUENTLY ASKED QUESTION
FREQUENTLY ASKED QUESTION
What Is Deep Cycling? Deep cycling is almost fully discharging a battery and then completely recharging it. Golf cart batteries are an example of lead-acid batteries that must be designed to be deep cycled. A golf cart must be able to cover two 18-hole rounds of golf and then be fully recharged overnight. Charging is hard on batteries because the internal heat generated can cause plate warpage, so these specially designed batteries use thicker plate grids that resist warpage. Normal automotive batteries are not designed for repeated deep cycling.
What Determines Battery Capacity? The capacity of any battery is determined by the amount of active plate material in the battery. A battery with a large number of thin plates can produce high current for a short period. If a few thick plates are used, the battery can produce low current for a long period. A trolling motor battery used for fishing must supply a low current for a long period of time. An automotive battery is required to produce a high current for a short period for cranking. Therefore, every battery is designed for a specific application.
50 amp-hour (A-H) rating can deliver 50 amperes for one hour or 1 ampere for 50 hours or any combination that equals 50 amp-hours. system for starting. The cold-cranking ampere rating of a battery is the number of amperes that can be supplied by a battery at 0°F (⫺18°C) for 30 seconds while the battery still maintains a voltage of 1.2 volts per cell or higher. This means that the battery voltage would be 7.2 volts for a 12 volt battery and 3.6 volts for a 6 volt battery. The cold-cranking performance rating is called cold-cranking amperes (CCA). Try to purchase a battery with the highest CCA for the money. See the vehicle manufacturer’s specifications for recommended battery capacity.
CRANKING AMPERES The designation CA refers to the number of amperes that can be supplied by a battery at 32°F (0°C). This rating results in a higher number than the more stringent CCA rating. SEE FIGURE 50–11.
BATTERY SIZES BCI GROUP SIZES
Battery sizes are standardized by the Battery Council International (BCI). When selecting a replacement battery, check the specified group number in service information, battery application charts at parts stores, or the owner’s manual.
TYPICAL GROUP SIZE APPLICATIONS
24/24F (top terminals). Fits many Honda, Acura, Infinity, Lexus, Nissan, and Toyota vehicles.
34/78 (dual terminals, both side and top posts). Fits many General Motors pickups and SUVs, as well as midsize and larger GM sedans and large Chrysler/Dodge vehicles.
35 (top terminals). Fits many Japanese brand vehicles.
65 (top terminals). Fits most large Ford/Mercury passenger cars, trucks, and SUVs.
75 (side terminals). Fits some General Motors small and midsize cars and some Chrysler/Dodge vehicles.
78 (side terminals). Fits many General Motors pickups and SUVs, as well as midsize and larger GM sedans.
MARINE CRANKING AMPERES
Marine cranking amperes (MCA) is similar to cranking amperes and is tested at 32°F (0°C).
RESERVE CAPACITY
The reserve capacity rating for batteries is the number of minutes for which the battery can produce 25 amperes and still have a battery voltage of 1.75 volts per cell (10.5 volts for a 12 volt battery). This rating is actually a measurement of the time for which a vehicle can be driven in the event of a charging system failure.
AMPERE HOUR Ampere hour is an older battery rating system that measures how many amperes of current the battery can produce over a period of time. For example, a battery that has a
Exact dimensions can be found on the Internet by searching for BCI battery sizes.
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REVIEW QUESTIONS 1. Why can discharged batteries freeze?
3. Why can a battery explode if it is exposed to an open flame or spark?
2. What are the battery-rating methods?
CHAPTER QUIZ 1. When a battery becomes completely discharged, both positive and negative plates become ______________ and the electrolyte becomes ______________. a. H2SO4 / Pb b. PbSO4 / H2O c. PbO2 / H2SO4 d. PbSO4 / H2SO4 2. A fully charged 12 volt battery should indicate ______________. a. 12.6 volts or higher b. A specific gravity of 1.265 or higher c. 12 volts d. Both a and b 3. Deep cycling means ______________. a. Overcharging the battery b. Overfilling or underfilling the battery with water c. The battery is fully discharged and then recharged d. The battery is overfilled with acid (H2SO4) 4. What makes a battery “low maintenance” or “maintenance free”? a. Material is used to construct the grids. b. The plates are constructed of different metals. c. The electrolyte is hydrochloric acid solution. d. The battery plates are smaller, making more room for additional electrolytes. 5. The positive battery plate is ______________. a. Lead dioxide b. Brown in color c. Sometimes called lead peroxide d. All of the above
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51
6. Which battery rating is tested at 0°F (⫺18°C)? a. Cold-cranking amperes (CCA) b. Cranking amperes (CA) c. Reserve capacity d. Battery voltage test 7. Which battery rating is expressed in minutes? a. Cold-cranking amperes (CCA) b. Cranking amperes (CA) c. Reserve capacity d. Battery voltage test 8. What battery rating is tested at 32°F (0°C)? a. Cold-cranking amperes (CCA) b. Cranking amperes (CA) c. Reserve capacity d. Battery voltage test 9. What gases are released from a battery when it is being charged? a. Oxygen b. Hydrogen c. Nitrogen and oxygen d. Hydrogen and oxygen 10. A charge indicator (eye) operates by showing green or red when the battery is charged and dark if the battery is discharged. This charge indicator detects ______________. a. Battery voltage b. Specific gravity c. Electrolyte water pH d. Internal resistance of the cells
BATTERY TESTING AND SERVICE
OBJECTIVES: After studying Chapter 51, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “B” (Battery Diagnosis and Service). • List the precautions necessary when working with batteries. • Explain how to safely charge a battery. • Discuss how to perform a battery drain test. • Describe how to perform a battery load test. • Explain how to conduct a conductance test. • Discuss how to test batteries for open-circuit voltage and specific gravity. KEY TERMS: Battery electrical drain test 552 • Dynamic voltage 546 • Hydrometer 547 • IOD 552 • Load test 547 • Open circuit voltage 546 • Parasitic load test 552 • Three-minute charge test 548
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FIGURE 51–1 A visual inspection on this battery shows the electrolyte level was below the plates in all cells.
BATTERY SERVICE SAFETY CONSIDERATIONS
FIGURE 51–2 Corrosion on a battery cable could be an indication that the battery itself is either being overcharged or is sulfated, creating a lot of gassing of the electrolyte. creating hot spots on the plates. When the battery is being charged, the acid fumes are forced out of the vent holes and onto the battery cables, connections, and even on the battery tray underneath the battery. SEE FIGURE 51–2.
HAZARDS
Batteries contain acid and release explosive gases (hydrogen and oxygen) during normal charging and discharging cycles.
SAFETY PROCEDURES
To help prevent physical injury or damage to the vehicle, always adhere to the following safety procedures. 1. When working on any electrical component on a vehicle, disconnect the negative battery cable from the battery. When the negative cable is disconnected, all electrical circuits in the vehicle will be open, which will prevent accidental electrical contact between an electrical component and ground. Any electrical spark has the potential to cause explosion and personal injury. 2. Wear eye protection (goggles preferred) when working around any battery. 3. Wear protective clothing to avoid skin contact with battery acid. 4. Always adhere to all safety precautions as stated in the service procedures for the equipment used for battery service and testing. 5. Never smoke or use an open flame around any battery.
SYMPTOMS OF A WEAK OR DEFECTIVE BATTERY
Slower than normal engine cranking. When the capacity of the battery is reduced due to damage or age, it is less likely to be able to supply the necessary current for starting the engine, especially during cold weather.
BATTERY MAINTENANCE NEED FOR MAINTENANCE Most new-style batteries are of a maintenance-free design that uses lead-calcium instead of leadantimony plate grid construction. Because lead-calcium batteries do not release as much gas as the older-style, lead-antimony batteries, there is less consumption of water during normal service. Also, with less gassing, less corrosion is observed on the battery terminals, wiring, and support trays. If the electrolyte level can be checked, and if it is low, add only distilled water. Distilled water is recommended by all battery manufacturers, but if distilled water is not available, clean ordinary drinking water, low in mineral content, can be used. Battery maintenance includes making certain that the battery case is clean and checking that the battery cables and hold-down fasteners are clean and tight. BATTERY TERMINAL CLEANING Many battery-related faults are caused by poor electrical connections at the battery. Battery cable connections should be checked and cleaned to prevent voltage drop at the connections. One common reason for an engine to not start is loose or corroded battery cable connections. Perform an inspection and check for the following conditions.
Loose or corroded connections at the battery terminals (should not be able to be moved by hand)
The following warning signs indicate that a battery is near the end of its useful life.
Loose or corroded connections at the ground connector on the engine block
Uses water in one or more cells. This indicates that the plates are sulfated and that during the charging process, the water in the electrolyte is being turned into separate hydrogen and oxygen gases. SEE FIGURE 51–1.
Wiring that has been modified to add auxiliary power for a sound system, or other electrical accessory
Excessive corrosion on battery cables or connections. Corrosion is more likely to occur if the battery is sulfated,
If the connections are loose or corroded, use 1 tablespoon of baking soda in 1 quart (liter) of water and brush this mixture onto the battery and housing to neutralize the acid. Mechanically clean the connections and wash the area with water. SEE FIGURE 51–3.
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FIGURE 51–3 Besides baking soda and water, a sugar-free diet soft drink can also be used to neutralize the battery acid.
TECH TIP Dynamic versus Open Circuit Voltage Open circuit voltage is the voltage (usually of a battery) that exists without a load being applied. Dynamic voltage is the voltage of the power source (battery) with the circuit in operation. A vehicle battery, for example, may indicate that it has 12.6 volts or more, but that voltage will drop when the battery is put under a load such as cranking the engine. If the battery voltage drops too much, the starter motor will rotate more slowly and the engine may not start. If the dynamic voltage is lower than specified, the battery may be weak or defective or the circuit may be defective.
(a)
BATTERY HOLD-DOWN
The battery should also be secured with a hold-down bracket to prevent vibration from damaging the plates inside the battery. The hold-down bracket should be snug enough to prevent battery movement, yet not so tight as to cause the case to crack. Factory-original hold-down brackets are often available through local automobile dealers, and universal hold-down units are available through local automotive parts stores.
BATTERY VOLTAGE TEST (b)
STATE OF CHARGE
Testing the battery voltage with a voltmeter is a simple method for determining the state of charge of any battery. SEE FIGURE 51–4. The voltage of a battery does not necessarily indicate whether the battery can perform satisfactorily, but it does indicate to the technician more about the battery’s condition than a simple visual inspection. A battery that “looks good” may not be good. This test is commonly called an open circuit battery voltage test because it is conducted with an open circuit, no current flowing, and no load applied to the battery. 1. If the battery has just been charged or the vehicle has recently been driven, it is necessary to remove the surface charge from the battery before testing. A surface charge is a charge of
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FIGURE 51–4 (a) A voltage reading of 12.28 volts indicates that the battery is not fully charged and should be charged before testing. (b) A battery that measures 12.6 volts or higher after the surface charge has been removed is 100% charged. higher-than-normal voltage that is just on the surface of the battery plates. The surface charge is quickly removed when the battery is loaded and therefore does not accurately represent the true state of charge of the battery. 2. To remove the surface charge, turn the headlights on high beam (brights) for one minute, then turn the headlights off and wait two minutes.
BATTERY VOLTAGE (V)
STATE OF CHARGE
12.6 or higher 12.4
100% charged
SPECIFIC GRAVITY
BATTERY VOLTAGE (V)
75% charged
1.265
12.6 or higher
100% charged
12.2
50% charged
1.225
12.4
75% charged
12.0
25% charged
1.190
12.2
50% charged
11.9 or lower
Discharged
1.155
12.0
25% charged
Lower than 1.120
11.9 or lower
Discharged
CHART 51–1
32 28
60C 140F
24
54.5C 130F
20
49C 120F
16
43C 110F
12
37.5C 100F
8
32.5C
90F
4
27C
80F
0 4
21C
70F
15.5C
60F
8
10C
50F
12
4.5C
40F
16
1C
30F
20
6.5C
20F
24
12C
10F
28
SUBTRACT
71C 160F 65.5C 150F
SUBTRACT
The estimated state of charge of a 12 volt battery after the surface charge has been removed.
EXAMPLE: HYDROMETER READING ELECTROLYTE TEMPERATURE SUBTRACT SPECIFIC GRAVITY CORRECTED SPECIFIC GRAVITY IS
1.250 40F .016 1.234
EXAMPLE: HYDROMETER READING ELECTROLYTE TEMPERATURE ADD SPECIFIC GRAVITY CORRECTED SPECIFIC GRAVITY IS
1.240 100F .008 1.248
STATE OF CHARGE
CHART 51–2 Measuring the specific gravity can detect a defective battery. A battery should be at least 75% charged before being load tested.
A FULLY CHARGED BATTERY HAS A SPECIFIC GRAVITY OF ABOUT 1.265
FIGURE 51–5 When testing a battery using a hydrometer, the reading must be corrected if the temperature is above or below 80°F (27°C).
FIGURE 51–6 This battery has cold-cranking amperes (CCA) of 550 A, cranking amperes (CA) of 680 A, and load test amperes of 270 A listed on the top label. Not all batteries have this complete information.
3. With the engine and all electrical accessories off, and the doors shut (to turn off the interior lights), connect a voltmeter to the battery posts. Connect the red positive lead to the positive post and the black negative lead to the negative post. NOTE: If the meter reads negative (⫺), the battery has been reverse charged (has reversed polarity) and should be replaced, or the meter has been connected incorrectly. 4. Read the voltmeter and compare the results with the state of charge. The voltages shown are for a battery at or near room temperature (70°F to 80°F, or 21°C to 27°C). SEE CHART 51–1.
HYDROMETER TESTING
BATTERY LOAD TESTING TERMINOLOGY One test to determine the condition of any battery is the load test. Most automotive starting and charging testers use a carbon pile to create an electrical load on the battery. The amount of the load is determined by the original CCA rating of the battery, which should be at least 75% charged before performing a load test. The capacity is measured in cold-cranking amperes, which is the number of amperes that a battery can supply at 0°F (⫺18°C) for 30 seconds. TEST PROCEDURE
To perform a battery load test, take the
following steps. If the battery has removable filler caps, the specific gravity of the electrolyte can also be checked. A hydrometer is a tester that measures the specific gravity. SEE FIGURE 51–5. This test can also be performed on most maintenance-free batteries because their filler caps are removable, except for those produced by Delco (Delphi) Battery. The specific gravity test indicates the state of battery charge and can indicate a defective battery if the specific gravity of one or more cells varies by more than 0.050 from the value of the highest-reading cell. SEE CHART 51–2.
STEP 1
Determine the CCA rating of the battery. The proper electrical load used to test a battery is half of the CCA rating or three times the ampere-hour rating, with a minimum 150 ampere load. SEE FIGURE 51–6.
STEP 2
Connect the load tester to the battery. Follow the instructions for the tester being used.
STEP 3
Apply the load for a full 15 seconds. Observe the voltmeter during the load testing and check the voltage at the end of the 15 sec. period while the battery is still under load. A good battery should indicate above 9.6 V.
BAT T E RY T E ST I N G A N D S ERVIC E
547
12 V (1000 A)
12 V (500 A)
12 V (500 A)
FIGURE 51–8 Most light-duty vehicles equipped with two batteries are connected in parallel as shown. Two 500 A, 12 volt batteries are capable of supplying 1,000 A at 12 volts, which is needed to start many diesel engines. FIGURE 51–7 An alternator regulator battery starter tester (ARBST) automatically loads the battery with a fixed load for 15 sec. to remove the surface charge, then removes the load for 30 sec. to allow the battery to recover, and then reapplies the load for another 15 sec. The results of the test are then displayed.
?
24 V (500 A)
FREQUENTLY ASKED QUESTION 12 V (500 A)
What Is the Three-Minute Charge Test? A three-minute charge test is used to check if a battery is sulfated, and is performed as follows: • Connect a battery charger and a voltmeter to the battery terminals. • Charge the battery at a rate of 40 amperes for three minutes. • At the end of three minutes, read the voltmeter.
FIGURE 51–9 Many heavy-duty trucks and buses use two 12 volt batteries connected in series to provide 24 volts.
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ELECTRONIC CONDUCTANCE TESTING TERMINOLOGY
General Motors Corporation, Chrysler Corporation, and Ford specify that an electronic conductance tester be used to test batteries in vehicles still under factory warranty. Conductance
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Many vehicles equipped with a diesel engine use two batteries. These batteries are usually electrically connected in parallel to provide additional current (amperes) at the same voltage. SEE FIGURE 51–8. Some heavy-duty trucks and buses connect two batteries in series to provide about the same current as one battery, but with twice the voltage, as shown in FIGURE 51–9. To successfully test the batteries, they should be disconnected and tested separately. If just one battery is found to be defective, most experts recommend that both be replaced to help prevent future problems. Because the two batteries are electrically connected, a fault in one battery can cause the good battery to discharge into the defective battery, thereby affecting both even if just one battery is at fault.
Repeat the test. Many battery manufacturers recommend performing the load test twice, using the first load period to remove the surface charge on the battery and the second test to provide a truer indication of the condition of the battery. Wait 30 seconds between tests to allow time for the battery to recover. SEE FIGURE 51–7.
Results: If the battery fails the load test, recharge the battery and retest. If the load test is failed again, replacement of the battery is required.
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FREQUENTLY ASKED QUESTION
How Should You Test a Vehicle Equipped with Two Batteries?
Results: If the voltage is above 15.5 volts, replace the battery. If the voltage is below 15.5 volts, the battery is not sulfated and should be charged and retested. This is not a valid test of many maintenance-free batteries, such as the Delphi Freedom. Due to the high internal resistance, a discharged Delphi Freedom battery may not start to accept a charge for several hours. Always use another alternative battery test before discarding a battery based on the results of the three-minute charge test.
STEP 4
12 V (500 A)
is a measure of how well a battery can create current. This tester sends a small signal through the battery and then measures a part of the AC response. As a battery ages, the plates can become sulfated and shed active materials from the grids, reducing the battery capacity. Conductance testers can be used to test flooded or absorbed glass (AGM) type batteries. The unit can determine the following information about a battery.
CCA
State of charge
Voltage of the battery
Defects such as shorts and opens
However, a conductance tester is not designed to accurately determine the state of charge or CCA rating of a new battery. Unlike a battery load test, a conductance tester can be used on a battery that is discharged. This type of tester should only be used to test batteries that have been in service. SEE FIGURE 51–10.
• Replace the battery. The battery is not serviceable and should be replaced. • Bad cell—replace. The battery is not serviceable and should be replaced. Some conductance testers can check the charging and cranking circuits, too.
TEST PROCEDURE STEP 1
Connect the unit to the positive and negative terminals of the battery. If testing a side post battery, always use the lead adapters and never use steel bolts as these can cause an incorrect reading. NOTE: Test results can be incorrectly reported on the display if proper, clean connections to the battery are not made. Also be sure that all accessories and the ignition switch are in the off position.
STEP 2
Enter the CCA rating (if known) and push the arrow keys.
STEP 3
The tester determines and displays one of the following: • Good battery. The battery can return to service. • Charge and retest. Fully recharge the battery and return it to service.
BATTERY CHARGING CHARGING PROCEDURE
If the state of charge of a battery is low, it must be recharged. It is best to slow charge any battery to prevent possible overheating damage to the battery. Perform the following steps. STEP 1
Determine the charge rate. The charge rate is based on the current state of charge (SOC) and charging rate. SEE CHART 51–3 for the recommended charging rate.
STEP 2
Connect a battery charger to the battery. Be sure the charger is not plugged in when connecting a charger to a
SAFETY TIP Never Charge or Jump Start a Frozen Battery A discharged battery can freeze because the electrolyte becomes mostly water. Never attempt to charge or jump start a vehicle that has a frozen battery. When the battery freezes, it often bulges at the sides because water expands about 9% when it freezes, forming ice crystals that occupy more space than liquid water. The crystals can trap bubbles of hydrogen and oxygen that are created during the chemical processes in a battery. When attempting to charge or jump start the frozen battery, these pockets of gases can explode. Because the electrolyte expands, the freezing action usually destroys the plates and can loosen the active material from the grids. It is rare for a frozen battery to be restored to useful service.
FIGURE 51–10 A conductance tester is very easy to use and has proved to accurately determine battery condition if the connections are properly made. Follow the instructions on the display exactly for best results.
OPEN CIRCUIT VOLTAGE
BATTERY SPECIFIC GRAVITY*
STATE OF CHARGE
CHARGING TIME TO FULL CHARGE AT 80°F** at 60 amps
at 50 amps
at 40 amps
at 30 amps
at 20 amps
at 10 amps
12.6
1.265
100%
FULL CHARGE
12.4
1.225
75%
15 min.
20 min.
27 min.
35 min.
48 min.
90 min.
12.2
1.190
50%
35 min.
45 min.
55 min.
75 min.
95 min.
180 min.
12.0
1.155
25%
50 min.
65 min.
85 min.
115 min.
145 min.
260 min.
11.8
1.120
0%
65 min.
85 min.
110 min.
150 min.
195 min.
370 min.
CHART 51–3 Battery charging guideline showing the charging times that vary according to state of charge, temperature, and charging rate. It may take eight hours or more to charge a fully discharged battery. *Correct for temperature **If colder, it’ll take longer
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TECH TIP Charge Batteries at 1% of Their CCA Rating Many batteries are damaged due to being overcharged. To help prevent damage such as warped plates and excessive release of sulfur smell gases, charge batteries at a rate equal to 1% of the battery’s CCA rating. For example, a battery with a 700 CCA rating should be charged at 7 amperes (700 ⫻ 0.01 ⫽ 7 amperes). No harm will occur to the battery at this charge rate even though it may take longer to achieve a full charge. This means that a battery may require eight or more hours to become fully charged depending on the battery capacity and state of charge (SOC).
TECH TIP Always Use Adapters on Side Post Batteries
FIGURE 51–11 A typical industrial battery charger. Be sure that the ignition switch is in the off position before connecting any battery charger. Connect the cables of the charger to the battery before plugging the charger into the outlet. This helps prevent a voltage spike and spark that could occur if the charger happened to be accidentally left on. Always follow the battery charger manufacturer’s instructions. battery. Always follow the battery charger’s instructions for proper use. STEP 3
Set the charging rate. The initial charge rate should be about 35 A for 30 minutes to help start the charging process. Fast charging a battery increases the temperature of the battery and can cause warping of the plates inside the battery. Fast charging also increases the amount of gassing (release of hydrogen and oxygen), which can create a health and fire hazard. The battery temperature should not exceed 125°F (hot to the touch). • Fast charge: 15 A maximum • Slow charge: 5 A maximum
Side post batteries require that an adapter be used when charging the battery, if it is removed from the vehicle. Do not use steel bolts. If a bolt is threaded into the terminal, only the parts of the threads that contact the battery terminal will be conducting all of the charging current. An adapter or a bolt with a nut attached is needed to achieve full contact with the battery terminals. SEE FIGURE 51–12.
BATTERY CHARGE TIME The time needed to charge a completely discharged battery can be estimated by using the reserve capacity rating of the battery in minutes divided by the charging rate. Hours needed to charge the battery = Reserve capacity Charge current For example, if a 10 A charge rate is applied to a discharged battery that has a 90-minute reserve capacity, the time needed to charge the battery will be nine hours. 90 minutes 10 A = 9 hours
SEE FIGURE 51–11.
CHARGING AGM BATTERIES Charging an absorbed glass mat (AGM) battery requires a different charger than is used to recharge a flooded-type battery. The differences include:
The AGM can be charged with high current, up to 75% of the ampere-hour rating due to lower internal resistance.
The charging voltage has to be kept at or below 14.4 volts to prevent damage.
Because most conventional battery chargers use a charging voltage of 16 volts or higher, a charger specifically designed to charge AGM batteries must be used. Absorbed glass mat batteries are often used as auxiliary batteries in hybrid electric vehicles when the battery is located inside the vehicle. SEE CHART 51–4 for a summary of the locations of the 12 volt auxiliary battery and high-voltage battery and safety switch/plug.
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JUMP STARTING To jump start another vehicle with a dead battery, connect goodquality copper jumper cables or a jump box to the good battery and the dead battery, as shown in FIGURE 51–13. When using jumper cables or a battery jump box, the last connection made should always be on the engine block or an engine bracket on the dead vehicle as far from the battery as possible. SEE FIGURE 51–14. It is normal for a spark to be created when the jumper cables finally complete the jumping circuit, and this spark could cause an explosion of the gases around the battery. Many newer vehicles have special ground and/or positive power connections built away from the battery just for the purpose of jump starting. Check the owner’s manual or service information for the exact location.
AUXILIARY 12 V BATTERY LOCATION
HV BATTERY PACK LOCATION (VOLTAGE)
Cadillac Escalade (2008+) (two mode)
Under the hood; driver’s side
Under second row seat (300 volts)
Flooded lead-acid
Chevrolet Malibu (2008+)
Under the hood; driver’s side
Mounted behind rear seat under vehicle floor (36 volts)
Flooded lead-acid
Chevrolet Silverado (2004–2008) (PHT)
Under the hood; driver’s side
Under second row seat (42 volts)
Flooded lead-acid
Chevrolet Tahoe (two mode)
Under the hood; driver’s side
Under second row seat (300 volts)
Flooded lead-acid
Chrysler Aspen (2009)
Under driver’s side door, under vehicle
Under rear seat; driver’s side (288 volts)
Flooded lead-acid
Dodge Durango (2009)
Under driver’s side door, under vehicle
Under rear seat; driver’s side (288 volts)
Flooded lead-acid
Ford Escape (2005+)
Under the hood; driver’s side
Cargo area in the rear under carpet (300 volts)
Flooded lead-acid
GMC Sierra (2004–2008) (PHT)
Under the hood; driver’s side
Under second row seat (42 volts)
Flooded lead-acid
GMC Yukon (2008+) (two mode)
Under the hood; driver’s side
Under second row seat (300 volts)
Flooded lead-acid
Honda Accord (2005–2007)
Under the hood; driver’s side
Behind rear seat (144 volts)
Flooded lead-acid
Honda Civic (2003+)
Under the hood; driver’s side
Behind rear seat (144 to 158 volts, 2006+)
Flooded lead-acid
Honda Insight (1999–2005)
Under the hood; center under windshield
144 volts; under hatch floor in the rear
Flooded lead-acid
Honda Insight (2010+)
Under the hood; driver’s side
144 volts; under floor behind rear seat
Flooded lead-acid
Lexus GS450h (2007+)
In the trunk; driver’s side, behind interior panel
Trunk behind rear seat (288 volts)
Absorbed glass mat (AGM)
Lexus LS 600h (2006+)
In the trunk; driver’s side, behind interior panel
Trunk behind rear seat (288 volts)
Absorbed glass mat (AGM)
Lexus RX400h (2006–2009)
Under the hood; passenger side
Under the second row seat (288 volts)
Flooded lead-acid
Mercury Mariner (2005+)
Under the hood; driver’s side
Cargo area in the rear under carpet (300 volts)
Flooded lead-acid
Nissan Altima (2007+)
In the trunk; driver’s side
Behind rear seat (245 volts)
Absorbed glass mat (AGM)
Saturn AURA Hybrid (2007+)
Under the hood; driver’s side
Behind the rear seat; under the vehicle floor (36 volts)
Flooded lead-acid
Saturn VUE Hybrid (2007+)
Under the hood; driver’s side
Behind the rear seat; under the vehicle floor (36 volts)
Flooded lead-acid
Toyota Camry Hybrid (2007+)
In the trunk; passenger side
Behind the rear seat; under the vehicle floor (245 volts)
Absorbed glass mat (AGM)
Toyota Highlander Hybrid (2006–2009)
Under the hood; passenger side
Under the second row seat (288 volts)
Flooded lead-acid
Toyota Prius (2001–2003)
In the trunk; driver’s side
Behind rear seat (274 volts)
Absorbed glass mat (AGM)
Toyota Prius (2004–2009)
In the trunk; driver’s side
Behind rear seat (201 volts)
Absorbed glass mat (AGM)
Toyota Prius (2010+)
In the trunk; driver’s side
Behind rear seat (201.6 volts)
Absorbed glass mat (AGM)
MAKE, MODEL (YEARS)
TYPE OF 12 V BATTERY
CHART 51–4 A summary chart showing where the 12 volt and high-voltage batteries and shut-off switch/plugs are located. Only the auxiliary 12 volt batteries can be serviced or charged.
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INSULATOR STRAP
CHARGING ADAPTER
ADAPTERS
FIGURE 51–13 A typical battery jump box used to jump start vehicles. These hand-portable units have almost made jumper cables obsolete.
FIGURE 51–12 Adapters should be used on side terminal batteries whenever charging.
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FREQUENTLY ASKED QUESTION
Should Batteries Be Kept Off of Concrete Floors? All batteries should be stored in a cool, dry place when not in use. Many technicians have been warned not to store or place a battery on concrete. According to battery experts, it is the temperature difference between the top and the bottom of the battery that causes a difference in the voltage potential between the top (warmer section) and the bottom (colder section). It is this difference in temperature that causes self-discharge to occur. In fact, submarines cycle seawater around their batteries to keep all sections of the battery at the same temperature to help prevent self-discharge. Therefore, always store or place batteries up off the floor and in a location where the entire battery can be kept at the same temperature, avoiding extreme heat and freezing temperatures. Concrete cannot drain the battery directly because the case of the battery is a very good electrical insulator.
FIGURE 51–14 Jumper cable usage guide. Notice that the last connection should be the engine block of the disabled vehicle to help prevent the spark that normally occurs from igniting the gases from the battery.
TECH TIP Look at the Battery Date Code
BATTERY ELECTRICAL DRAIN TEST TERMINOLOGY The battery electrical drain test determines if any component or circuit in a vehicle is causing a drain on the battery when everything is off. This test is also called the ignition off draw (IOD) or parasitic load test. Many electronic components draw a continuous, slight amount of current from the battery when the ignition is off. These components include: 1. Electronically tuned radios for station memory and clock circuits 2. Computers and controllers, through slight diode leakage 3. The alternator, through slight diode leakage These components may cause a voltmeter to read full battery voltage if it is connected between the negative battery terminal and the removed end of the negative battery cable. Because of
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All major battery manufacturers stamp codes on the battery case that give the date of manufacture and other information. Most battery manufacturers use a number to indicate the year of manufacture and a letter to indicate the month of manufacture, except the letter I, because it can be confused with the number 1. For example: A = January
G = July
B = February
H = August
C = March
J = September
D = April
K = October
E = May
L = November
F = June
M = December
The shipping date from the manufacturing plant is usually indicated by a sticker on the end of the battery. Almost every battery manufacturer uses just one letter and one number to indicate the month and year. SEE FIGURE 51–15.
FIGURE 51–15 The code on the Delphi battery indicates that it was built in 2005 (5), in February (B), on the eleventh day (11), during third shift (C), and in the Canadian plant (Z).
FIGURE 51–16 This mini clamp-on digital multimeter is being used to measure the amount of battery electrical drain that is present. In this case, a reading of 20 mA (displayed on the meter as 00.02 A) is within the normal range of 20 to 30 mA. Be sure to clamp around all of the positive battery cable or all of the negative battery cable, whichever is easiest to get the clamp around.
this fact, voltmeters should not be used for battery drain testing. This test should be performed when one of the following conditions exists. 1. When a battery is being charged or replaced (a battery drain could have been the cause for charging or replacing the battery) 2. When the battery is suspected of being drained
PROCEDURE FOR BATTERY ELECTRICAL DRAIN TEST
Inductive DC ammeter. The fastest and easiest method to measure battery electrical drain is to connect an inductive DC ammeter that is capable of measuring low current (10 mA). SEE FIGURE 51–16 for an example of a clamp-on digital multimeter being used to measure battery drain.
DMM set to read milliamperes. Following is the procedure for performing the battery electrical drain test using a DMM set to read DC amperes. STEP 1 Make certain that all lights, accessories, and ignition are off. STEP 2 Check all vehicle doors to be certain that the interior courtesy (dome) lights are off. STEP 3 Disconnect the negative (⫺) battery cable and install a parasitic load tool, as shown in FIGURE 51–17. STEP 4 Start the engine and drive the vehicle about 10 minutes, being sure to turn on all the lights and accessories including the radio. STEP 5 Turn the engine and all accessories off including the underhood light. STEP 6 Connect an ammeter across the parasitic load tool switch and wait 20 minutes for all computers and circuits to shut down. STEP 7 Open the switch on the load tool and read the battery electrical drain on the meter display.
NOTE: Using a voltmeter or test light to measure battery drain is not recommended by most vehicle manufacturers. The high internal resistance of the voltmeter results in an irrelevant reading that does not provide the technician with adequate information about a problem.
FIGURE 51–17 After connecting the shut-off tool, start the engine and operate all accessories. Stop the engine and turn off everything. Connect the ammeter across the shut-off switch in parallel. Wait 20 minutes. This time allows all electronic circuits to “time out” or shut down. Open the switch—all current now will flow through the ammeter. A reading greater than specified (usually greater than 50 mA, or 0.05 A) indicates a problem that should be corrected.
SPECIFICATIONS
Results:
Normal = 20 to 30 mA (0.02 to 0.03 A)
Maximum allowable = 50 mA (0.05 A)
RESET ALL MEMORY FUNCTIONS Be sure to reset the clock, “auto up” windows, and antitheft radio if equipped. SEE FIGURE 51–18. BATTERY DRAIN AND RESERVE CAPACITY It is normal for a battery to self-discharge even if there is not an electrical load such as computer memory to drain the battery. According to General Motors, this self-discharge is about 13 mA (0.013 A). Some vehicle manufacturers specify a maximum allowable parasitic draw or battery drain be based on the reserve capacity of the battery. The calculation used is the reserve capacity of the battery divided by 4; this equals the maximum allowable battery drain.
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BATTERY REPLACEMENT STRAP #270-325
DIODE #276-1103
9-VOLT BATTERY
AUTO DC PLUG FOR LIGHTER SOCKET #270-028
(a) DIODE
FIGURE 51–18 The battery was replaced in this Acura and the radio displayed “code” when the replacement battery was installed. Thankfully, the owner had the five-digit code required to unlock the radio.
REAL WORLD FIX The Chevrolet Battery Story A 2005 Chevrolet Impala was being diagnosed for a dead battery. Testing for a battery drain (parasitic draw) showed 2.25 A, which was clearly over the acceptable value of 0.050 or less. At the suggestion of the shop foreman, the technician used a Tech 2 scan tool to check if all of the computers and modules went to sleep after the ignition was turned off. The scan tool display indicated that the instrument panel (IP) showed that it remained awake after all of the others had gone into sleep mode. The IP cluster was unplugged and the vehicle was tested for an electrical drain again. This time, it was only 32 mA (0.032 A), well within the normal range. Replacing the IP cluster solved the excessive battery drain.
9-VOLT BATTERY
AUTO DC PLUG FOR LIGHTER SOCKET
(b) FIGURE 51–19 (a) Memory saver. The part numbers represent components from Radio Shack. (b) A schematic drawing of the same memory saver. Some experts recommend using a 12 volt lantern battery instead of a small 9 volt battery to help ensure that there will be enough voltage in the event that a door is opened while the vehicle battery is disconnected. Interior lights could quickly drain a small 9 volt battery.
For example, a battery rated at 120 minutes reserve capacity should have a maximum battery drain of 30 mA. 120 minutes reserve capacity 4 = 30 mA
TECH TIP It Could Happen to You!
FINDING THE SOURCE OF THE DRAIN
If there is a drain, check and temporarily disconnect the following components. 1. Underhood light 2. Glove compartment light 3. Trunk light If after disconnecting these three components the battery drain draws more than 50 mA (0.05 A), disconnect one fuse at a time from the fuse box until the excessive drain drops to normal.
NOTE: Do not reinsert fuses after they have been removed as this action can cause modules to “wake up,” leading to an inconclusive test. If the excessive battery drain stops after one fuse is disconnected, the source of the drain is located in that particular circuit, as labeled on the fuse box. Continue to disconnect the power-side wire connectors from each component included in that particular circuit until the test light goes off. The source of the battery drain can then be traced to an individual component or part of one circuit.
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The owner of a Toyota replaced the battery. After doing so, the owner noted that the “airbag” amber warning lamp was lit and the radio was locked out. The owner had purchased the vehicle used and did not know the four-digit security code needed to unlock the radio. Determined to fix the problem, the owner tried three four-digit numbers, hoping that one of them would work. However, after three tries, the radio became permanently disabled. Frustrated, the owner went to a dealer. It cost over $300 to fix the problem. A special tool was required to easily reset the airbag lamp. The radio had to be removed and sent out of state to an authorized radio service center and then reinstalled into the vehicle. Therefore, before disconnecting the battery, check to be certain that the owner has the security code for a security-type radio. A “memory saver” may be needed to keep the radio powered up when the battery is being disconnected. SEE FIGURE 51–19.
TECH TIP Check the Battery Condition First A discharged or defective battery has lower voltage potential than a good battery that is at least 75% charged. This lower battery voltage cannot properly power the starter motor. A weak battery could also prevent the charging voltage from reaching the voltage regulator cutoff point. This lower voltage could be interpreted as indicating a defective alternator and/or voltage regulator. If the vehicle continues to operate with low system voltage, the stator winding in the alternator can be overheated, causing alternator failure.
FIGURE 51–20 Many newer vehicles have batteries that are sometimes difficult to find. Some are located under plastic panels under the hood, under the front fender, or even under the rear seat as shown here.
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BATTERY SYMPTOM GUIDE The following list will assist technicians in troubleshooting batteries.
FREQUENTLY ASKED QUESTION
Where Is the Battery? Many vehicle manufacturers today place the battery under the backseat, under the front fender, or in the trunk. SEE FIGURE 51–20. Often, the battery is not visible even if it is located under the hood. When testing or jump starting a vehicle, look for a battery access point.
WHAT TO DO IF A BATTERY DRAIN STILL EXISTS If all the fuses have been disconnected and the drain still exists, the source of the drain has to be between the battery and the fuse box. The most common sources of drain under the hood include the following: 1. The alternator. Disconnect the alternator wires and retest. If the ammeter now reads a normal drain, the problem is a defective diode(s) in the alternator. 2. The starter solenoid (relay) or wiring near its components. These are also a common source of battery drain, due to high current flows and heat, which can damage the wire or insulation.
Problem
Possible Causes and/or Solutions
1. Headlights are dimmer than normal.
1. Discharged battery or poor connections on the battery, engine, or body
2. Solenoid clicks.
2. Discharged battery or poor connections on the battery or an engine fault, such as coolant on top of the pistons, causing a hydrostatic lock
3. Engine is slow in cranking.
3. Discharged battery, high-resistance battery cables, or defective starter or solenoid
4. Battery will not accept a charge.
4. Possible loose battery cable connections (If the battery is a maintenance-free type, attempt to fast charge the battery for several hours. If the battery still will not accept a charge, replace the battery.)
5. Battery is using water.
5. Check charging system for too high a voltage (If the voltage is normal, the battery is showing signs of gradual failure. Load test and replace the battery, if necessary.)
REVIEW QUESTIONS 1. What are the results of a voltmeter test of a battery and its state of charge?
3. How is a battery drain test performed? 4. Why should a battery not be fast charged?
2. What are the steps for performing a battery load test?
CHAPTER QUIZ 1. Technician A says that distilled or clean drinking water should be added to a battery when the electrolyte level is low. Technician B says that fresh electrolyte (solution of acid and water) should be added. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
2. All batteries should be in a secure bracket that is bolted to the vehicle to prevent physical damage to the battery. a. True b. False
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3. A battery date code sticker indicates D6. What does this mean? a. The date it was shipped from the factory was December 2006. b. The date it was shipped from the factory was April 2006. c. The battery expires in December 2002. d. It was built the second day of the week (Tuesday). 4. Many vehicle manufacturers recommend that a special electrical connector be installed between the battery and the battery cable when testing for ______________. a. Battery drain (parasitic drain) b. Specific gravity c. Battery voltage d. Battery charge rate 5. When load testing a battery, which battery rating is often used to determine how much load to apply to the battery? a. CA b. RC c. MCA d. CCA 6. When measuring the specific gravity of the electrolyte, the maximum allowable difference between the highest and lowest hydrometer reading is ______________. a. 0.010 b. 0.020 c. 0.050 d. 0.50
chapter
7. A battery high-rate discharge (load capacity) test is being performed on a 12 volt battery. Technician A says that a good battery should have a voltage reading of higher than 9.6 volts while under load at the end of the 15 sec. test. Technician B says that the battery should be discharged (loaded) to twice its CCA rating. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 8. When charging a lead-acid (flooded-type) battery, ____________. a. The initial charging rate should be about 35 amperes for 30 minutes b. The battery may not accept a charge for several hours, yet may still be a good (serviceable) battery c. The battery temperature should not exceed 125°F (hot to the touch) d. All of the above 9. Normal battery drain (parasitic drain) in a vehicle with many computer and electronic circuits is ______________. a. 20 to 30 milliamperes c. 150 to 300 milliamperes b. 2 to 3 amperes d. None of the above 10. When jump starting, ______________. a. The last connection should be the positive post of the dead battery b. The last connection should be the engine block of the dead vehicle c. The alternator must be disconnected on both vehicles d. Both a and c
CRANKING SYSTEM
52 OBJECTIVES: After studying Chapter 52, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “C” (Starting System Diagnosis and Repair). • Describe how the cranking circuit works. • Discuss how a starter motor converts electrical power into mechanical power. • Describe the hold-in and pull-in windings of a starter solenoid. KEY TERMS: Armature 560 • Brush-end housing 560 • Brushes 561 • CEMF 559 • Commutator-end housing 560 • Commutator segments 561 • Compression spring 563 • Drive-end housing 560 • Field coils 560 • Field housing 560 • Field poles 560 • Ground brushes 561 • Hold-in winding 564 • Insulated brushes 561 • Mesh spring 563 • Neutral safety switch 557 • Overrunning clutch 563 • PM starter 560 • Pole shoes 560 • Pull-in winding 564 • RVS 558 • Starter drive 562 • Starter solenoid 564 • Through bolts 560
CRANKING CIRCUIT PARTS INVOLVED
For any engine to start, it must first be rotated using an external power source. It is the purpose and function of the cranking circuit to create the necessary power and transfer it from the battery to the starter motor, which rotates the engine. The cranking circuit includes those mechanical and electrical components required to crank the engine for starting. The cranking
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force in the early 1900s was the driver’s arm, because the driver had to physically crank the engine until it started. Modern cranking circuits include the following: 1. Starter motor. The starter is normally a 0.5 to 2.6 horsepower (0.4 to 2 kilowatts) electric motor that can develop nearly 8 horsepower (6 kilowatts) for a very short time when first cranking a cold engine. SEE FIGURE 52–1. 2. Battery. The battery must be of the correct capacity and be at least 75% charged to provide the necessary current and voltage for correct starter operation.
IGNITION SWITCH
SOLENOID B
MANUAL TRANSMISSION
S
CLUTCH SWITCH
STARTER MOTOR
SOLENOID
AUTOMATIC TRANSMISSION
B S
BATTERY TRANSMISSION NEUTRAL SAFETY SWITCH
FIGURE 52–1 A typical solenoid-operated starter. STARTER
IGNITION LOCK AND KEY
FIGURE 52–3 To prevent the engine from cranking, an electrical switch is usually installed to open the circuit between the ignition switch and the starter solenoid.
used to be sure that the vehicle will not move when being cranked include the following:
IGNITION SWITCH ASSEMBLY
Many automobile manufacturers use an electric switch called a neutral safety switch, which opens the circuit between the ignition switch and the starter to prevent starter motor operation, unless the gear selector is in neutral or park. The safety switch can be attached either to the steering column inside the vehicle near the floor or on the side of the transmission.
Many manufacturers use a mechanical blocking device in the steering column to prevent the driver from turning the key switch to the start position unless the gear selector is in neutral or park.
Many manual transmission vehicles also use a safety switch to permit cranking only if the clutch is depressed. This switch is commonly called the clutch safety switch. SEE FIGURE 52–3.
FIGURE 52–2 Some column-mounted ignition switches act directly on the electrical ignition switch itself, whereas others use a link from the lock cylinder to the ignition switch.
3. Starter solenoid or relay. The high current required by the starter must be able to be turned on and off. A large switch would be required if the current were controlled by the driver directly. Instead, a small current switch (ignition switch) operates a solenoid or relay that controls the high current to the starter. 4. Starter drive. The starter drive uses a small pinion gear that contacts the engine flywheel gear teeth and transmits starter motor power to rotate the engine. 5. Ignition switch. The ignition switch and safety control switches control the starter motor operation. SEE FIGURE 52–2.
CONTROL CIRCUIT PARTS AND OPERATION
The engine is cranked by an electric motor that is controlled by a key-operated ignition switch. The ignition switch will not operate the starter unless the automatic transmission is in neutral or park, or the clutch pedal is depressed on manual transmission/transaxle vehicles. This is to prevent an accident that might result from the vehicle moving forward or rearward when the engine is started. The types of controls that are
COMPUTER-CONTROLLED STARTING OPERATION Some key-operated ignition systems and most push-button-to-start systems use the computer to crank the engine. The ignition switch start position on the push-to-start button is used as an input signal to the powertrain control module (PCM). Before the PCM cranks the engine, the following conditions must be met.
The brake pedal is depressed.
The gear selector is in park or neutral.
The correct key fob (code) is present in the vehicle.
A typical push-button start system includes the following sequence.
The ignition key can be turned to the start position, released, and the PCM cranks the engine until it senses that the engine has started.
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FIELD COILS
POLE SHOES S
N
GROUND BRUSH
FIGURE 52–4 Instead of using an ignition key to start the engine, some vehicles are using a start button which is also used to stop the engine, as shown on this Jaguar.
“HOT” BRUSH COMMUTATOR
TO OUTPUT TERMINAL OF SOLENOID
STARTER CASE GROUND
FIGURE 52–6 This series-wound electric motor shows the basic operation with only two brushes: one hot brush and one ground brush. The current flows through both field coils, then through the hot brush and the loop winding of the armature, before reaching ground through the ground brush.
S
“PILING UP” OF MAGNETIC LINES OF FORCE – FROM FIELD COIL AND LINES SURROUNDING ARMATURE LOOP CONDUCTOR
FIGURE 52–5 The top button on this key fob is the remote start button.
The PCM can detect that the engine has started by looking at the engine speed signal.
Normal cranking speed can vary between 100 and 250 RPM. If the engine speed exceeds 400 RPM, the PCM determines that the engine started and opens the circuit to the “S” (start) terminal of the starter solenoid that stops the starter motor.
Computer-controlled starting is almost always part of the system if a push-button start is used. SEE FIGURE 52–4.
REMOTE STARTING Remote starting, sometimes called remote vehicle start (RVS), is a system that allows the driver to start the engine of the vehicle from inside the house or a building at a distance of about 200 ft (65 m). The doors remain locked to reduce the possibility of theft. This feature allows the heating or air-conditioning system to start before the driver arrives. SEE FIGURE 52–5. NOTE: Most remote start systems will turn off the engine after 10 minutes of run time unless reset by using the remote.
STARTER MOTOR OPERATION PRINCIPLES A starter motor uses electromagnetic principles to convert electrical energy from the battery (up to 300 amperes) to mechanical power (up to 8 horsepower [6 kilowatts]) to crank the
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FIELD COIL MAGNETS ONE “LOOP” OF ARMATURE CARRYING A CURRENT
N
FIGURE 52–7 The interaction of the magnetic fields of the armature loops and field coils creates a stronger magnetic field on the right side of the conductor, causing the armature loop to move toward the left.
engine. Current for the starter motor or power circuit is controlled by a solenoid or relay, which is itself controlled by the driver-operated ignition switch. The current travels through the brushes and into the armature windings, where other magnetic fields are created around each copper wire loop in the armature. The two strong magnetic fields created inside the starter housing create the force that rotates the armature. Inside the starter housing is a strong magnetic field created by the field coil magnets. The armature, a conductor, is installed inside this strong magnetic field, with little clearance between the armature and the field coils. The two magnetic fields act together, and their lines of force “bunch up” or are strong on one side of the armature loop wire and become weak on the other side of the conductor. This causes the conductor (armature) to move from the area of strong magnetic field strength toward the area of weak magnetic field strength. SEE FIGURES 52–6 AND 52–7. The difference in magnetic field strength causes the armature to rotate. This rotation force (torque) is increased as the current flowing through the starter motor increases. The torque of a starter is
AIR GAP
N CONDUCTOR MOTION
WINDINGS
ARMATURE
POLE SHOE N
S
(a)
N
NT
RE
UR
FC
T
EC
DIR
O ION
S
CONDUCTOR MOTION
S
S
(b) N
FIGURE 52–9 Magnetic lines of force in a four-pole motor. S
N FIELD WINDINGS
ROTATION
(c) POLE SHOE POLE SHOE
S
N
POLE SHOE
FIGURE 52–10 A pole shoe and field winding. ROTATION
the motor. Pole shoes that do not have field windings are magnetized by flux lines from the wound poles.
SERIES MOTORS (d) FIGURE 52–8 The armature loops rotate due to the difference in the strength of the magnetic field. The loops move from a strong magnetic field strength toward a weaker magnetic field strength.
determined by the strength of the magnetic fields inside the starter. Magnetic field strength is measured in ampere-turns. If the current or the number of turns of wire is increased, the magnetic field strength is increased. The magnetic field of the starter motor is provided by two or more pole shoes and field windings. The pole shoes are made of iron and are attached to the frame with large screws. SEE FIGURE 52–8. FIGURE 52–9 shows the paths of magnetic flux lines within a four-pole motor. The field windings are usually made of a heavy copper ribbon to increase their current-carrying capacity and electromagnetic field strength. SEE FIGURE 52–10. Automotive starter motors usually have four pole shoes and two to four field windings to provide a strong magnetic field within
A series motor develops its maximum torque at the initial start (0 RPM) and develops less torque as the speed increases.
A series motor is commonly used for an automotive starter motor because of its high starting power characteristics.
A series starter motor develops less torque at high RPM, because a current is produced in the starter itself that acts against the current from the battery. Because this current works against battery voltage, it is called counterelectromotive force, or CEMF. This CEMF is produced by electromagnetic induction in the armature conductors, which are cutting across the magnetic lines of force formed by the field coils. This induced voltage operates against the applied voltage supplied by the battery, which reduces the strength of the magnetic field in the starter.
Because the power (torque) of the starter depends on the strength of the magnetic fields, the torque of the starter decreases as the starter speed increases. A series-wound starter also draws less current at higher speeds and will keep increasing in speed under light loads. This could lead to the destruction of the starter motor unless controlled or prevented. SEE FIGURE 52–11.
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ARMATURE
A SERIES COIL
FIGURE 52–11 This wiring diagram illustrates the construction of a series-wound electric motor. Notice that all current flows through the field coils, then through the armature (in series) before reaching ground.
A ARMATURE
FIGURE 52–12 This wiring diagram illustrates the construction of a shunt-type electric motor, and shows the field coils in parallel (or shunt) across the armature. ARMATURE SERIES COIL
DRIVE END HOUSING (END FRAME)
FIGURE 52–14 A typical starter motor showing the drive-end housing.
A
SHUNT COIL
FIGURE 52–13 A compound motor is a combination of series and shunt types, using part of the field coils connected electrically in series with the armature and some in parallel (shunt).
SHUNT MOTORS
Shunt-type electric motors have the field coils in parallel (or shunt) across the armature. A shunt-type motor has the following features.
A shunt motor does not decrease in torque at higher motor RPM, because the CEMF produced in the armature does not decrease the field coil strength.
A shunt motor, however, does not produce as high a starting torque as that of a series-wound motor, and is not used for starters. Some small electric motors, such as used for windshield wiper motors, use a shunt motor but most use permanent magnets rather than electromagnets.
HOW THE STARTER MOTOR WORKS PARTS INVOLVED
A starter consists of the main structural support of a starter called the main field housing, one end of which is called a commutator-end (or brush-end) housing and the other end a drive-end housing. The drive-end housing contains the drive pinion gear, which meshes with the engine flywheel gear teeth to start the engine. The commutator-end plate supports the end containing the starter brushes. Through bolts hold the three components together. SEE FIGURE 52–14.
Field coils. The steel housing of the starter motor contains permanent magnets or four electromagnets that are connected directly to the positive post of the battery to provide a strong magnetic field inside the starter. The four electromagnets use heavy copper or aluminum wire wrapped around a soft-iron core, which is contoured to fit against the rounded internal surface of the starter frame. The soft-iron cores are called pole shoes. Two of the four pole shoes are wrapped with copper wire in one direction to create a north pole magnet, and the other two pole shoes are wrapped in the opposite direction to create a south pole magnet. These magnets, when energized, create strong magnetic fields inside the starter housing and, therefore, are called field coils. The soft-iron cores (pole shoes) are often called field poles. SEE FIGURE 52–15.
Armature. Inside the field coils is an armature that is supported with either bushings or ball bearings at both ends, which permit it to rotate. The armature is constructed of thin, circular disks of steel laminated together and wound lengthwise with heavy-gauge insulated copper wire. The laminated iron core supports the copper loops of wire and helps concentrate the magnetic field produced by the coils. SEE FIGURE 52–16.
SEE FIGURE 52–12.
PERMANENT MAGNET MOTORS
A permanent magnet (PM) starter uses permanent magnets that maintain constant field strength, the same as a shunt-type motor, so they have similar operating characteristics. To compensate for the lack of torque, all PM starters use gear reduction to multiply starter motor torque. The permanent magnets used are an alloy of neodymium, iron, and boron, and are almost 10 times more powerful than previously used permanent magnets.
COMPOUND MOTORS
A compound-wound, or compound, motor has the operating characteristics of a series motor and a shunt-type motor, because some of the field coils are connected to the armature in series and some (usually only one) are connected directly to the battery in parallel (shunt) with the armature. Compound-wound starter motors are commonly used in Ford, Chrysler, and some GM starters. The shunt-wound field coil is called a shunt coil and is used to limit the maximum speed of the starter. Because the shunt coil is energized as soon as the battery current is sent to the starter, it is used to engage the starter drive on older Ford positive engagement–type starters. SEE FIGURE 52–13.
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HOUSING (FIELD FRAME)
Insulation between the laminations helps to increase the magnetic efficiency in the core. For reduced resistance, the armature conductors are made of a thick copper wire. The two ends of each conductor are attached to two adjacent commutator bars.
LAP WINDING POLE SHOE
POLE SHOE MOUNTING SCREW
NORTH POLE
SOUTH POLE
CONDUCTOR
FIELD COIL
FIGURE 52–15 Pole shoes and field windings installed in the housing.
BAR BRUSHES
FIGURE 52–17 An armature showing how its copper wire loops are connected to the commutator.
ARMATURE WINDING
ARMATURE SHAFT ARMATURE CORE
COMMUTATOR
ARMATURE CORE ASSEMBLY
ASSEMBLED ARMATURE
ARMATURE LAMINATION
FIGURE 52–16 A typical starter motor armature. The armature core is made from thin sheet metal sections assembled on the armature shaft, which is used to increase the magnetic field strength.
The commutator is made of copper bars insulated from each other by mica or some other insulating material. SEE FIGURE 52–17. The armature core, windings, and commutator are assembled on a long armature shaft. This shaft also carries the pinion gear that meshes with the engine flywheel ring gear.
STARTER BRUSHES To supply the proper current to the armature, a four-pole motor must have four brushes riding on the commutator. Most automotive starters have two grounded and two insulated brushes, which are held against the commutator by spring force. The ends of the copper armature windings are soldered to commutator segments. The electrical current that passes through the field coils is then connected to the commutator of the armature by brushes that can move over the segments of the rotating armature. These brushes are made of a combination of copper and carbon.
The copper is a good conductor material.
The carbon added to the starter brushes helps provide the graphite-type lubrication needed to reduce wear of the brushes and the commutator segments.
The starter uses four brushes—two brushes to transfer the current from the field coils to the armature, and two brushes to provide the ground return path for the current that flows through the armature.
The two sets of brushes include: 1. Two insulated brushes, which are in holders and are insulated from the housing. 2. Two ground brushes, which use bare, stranded copper wire connections to the brushes. The ground brush holders are not insulated and attach directly to the field housing or brush-end housing.
SEE FIGURE 52–18.
PERMANENT MAGNET FIELDS Permanent magnets are used in place of the electromagnetic field coils and pole shoes in many starters today. This eliminates the motor field circuit, which in turn eliminates the potential for field coil faults and other electrical problems. The motor has only an armature circuit.
GEAR-REDUCTION STARTERS PURPOSE AND FUNCTION
Gear-reduction starters are used by many automotive manufacturers. The purpose of the gear reduction (typically 2:1 to 4:1) is to increase starter motor speed and provide the torque multiplication necessary to crank an engine.
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SOLENOID PLUNGER RETURN SPRING
SOLENOID WINDINGS
SOLENOID
CONTACT POINT
TERMINAL
SOLENOID PLUNGER MOVING CONTACT POINT
SHIFT LEVER
STARTER END FRAME
MESHING SPRING
BRUSH SPRING
BRAKE DISC
COMMUTATOR DRIVER
PINION GEAR
BRUSH
ARMATURE SHAFT OVERRUNNING CLUTCH
STOP GUIDE RING
FIELD WINDING
STARTER HOUSING POLE PIECE ARMATURE
FIGURE 52–18 A cutaway of a typical starter motor showing the commutator, brushes, and brush spring.
REDUCTION GEARS
PLUNGER
FIGURE 52–19 This starter permanent magnet field housing was ruined when someone used a hammer on the field housing in an attempt to “fix” a starter that would not work. A total replacement is the only solution in this case.
TECH TIP Don’t Hit That Starter! In the past, it was common to see service technicians hitting a starter in their effort to diagnose a no-crank condition. Often the shock of the blow to the starter aligned or moved the brushes, armature, and bushings. Many times, the starter functioned after being hit, even if only for a short time. However, most starters today use permanent magnet fields, and the magnets can be easily broken if hit. A magnet that is broken becomes two weaker magnets. Some early PM starters used magnets that were glued or bonded to the field housing. If struck with a heavy tool, the magnets could be broken with parts of the magnet falling onto the armature and into the bearing pockets, making the starter impossible to repair or rebuild. SEE FIGURE 52–19.
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CHAPTER 5 2
FLEX PLATE OVER-RUNNING CLUTCH PINION GEAR
FIGURE 52–20 A typical gear-reduction starter. As a series-wound motor increases in rotational speed, the starter produces less power, and less current is drawn from the battery because the armature generates greater CEMF as the starter speed increases. However, a starter motor’s maximum torque occurs at 0 RPM and torque decreases with increasing RPM. A smaller starter using a gear-reduction design can produce the necessary cranking power with reduced starter amperage requirements. Lower current requirements mean that smaller battery cables can be used. Many permanent magnet starters use a planetary gear set (a type of gear reduction) to provide the necessary torque for starting. SEE FIGURE 52–20.
STARTER DRIVES PURPOSE AND FUNCTION
A starter drive includes small pinion gears that mesh with and rotate the larger gear on the engine flywheel or flex plate for starting. The pinion gear must engage with
MESH SPRING
CLUTCH HOUSING
SHELL
ROLLER RETAINER ROLLER SPRING
(a)
DRIVE FLANGE
BUSHING ROLLER COLLAR
PINION
FIGURE 52–21 A cutaway of a typical starter drive showing all of the internal parts.
FIGURE 52–23 Operation of the overrunning clutch. (a) Starter motor is driving the starter pinion and cranking the engine. The rollers are wedged against spring force into their slots. (b) The engine has started and is rotating faster than the starter armature. Spring force pushes the rollers so they can rotate freely.
?
FREQUENTLY ASKED QUESTION
What Is a Bendix?
200 TEETH FLYWHEEL RING GEAR
STARTER PINION GEAR
FIGURE 52–22 The ring gear to pinion gear ratio is usually 15:1 to 20:1. the engine gear slightly before the starter motor rotates, to prevent serious damage to either the starter gear or the engine, but must be disengaged after the engine starts. The ends of the starter pinion gear are tapered to help the teeth mesh more easily without damaging the flywheel ring gear teeth. SEE FIGURE 52–21.
STARTER DRIVE GEAR RATIO
The ratio of the number of teeth on the engine ring gear to the number on the starter pinion is between 15:1 and 20:1. A typical small starter pinion gear has 9 teeth that turn an engine ring gear with 166 teeth. This provides an 18:1 gear reduction; thus, the starter motor is rotating approximately 18 times faster than the engine. Normal cranking speed for the engine is 200 RPM (varies from 70 to 250 RPM). This means that the starter motor speed is 18 times faster, or 3600 starter RPM (200 ⫻ 18 ⫽ 3600). If the engine starts and is accelerated to 2000 RPM (normal cold engine speed), the starter will be destroyed by the high speed (36,000 RPM) if the starter was not disengaged from the engine. SEE FIGURE 52–22.
STARTER DRIVE OPERATION
(b)
All starter drive mechanisms use a type of one-way clutch that allows the starter to rotate the engine, but then turns freely if the engine speed is greater than the starter motor speed. This clutch, called an overrunning clutch, protects the starter motor from damage if the ignition switch is held
Older-model starters often used a Bendix drive mechanism, which used inertia to engage the starter pinion with the engine flywheel gear. Inertia is the tendency of a stationary object to remain stationary, because of its weight, unless forced to move. On these older-model starters, the small starter pinion gear was attached to a shaft with threads, and the weight of this gear caused it to be spun along the threaded shaft and mesh with the flywheel whenever the starter motor spun. If the engine speed was greater than the starter speed, the pinion gear was forced back along the threaded shaft and out of mesh with the flywheel gear. The Bendix drive mechanism has generally not been used since the early 1960s, but some technicians use this term when describing a starter drive.
in the start position after the engine starts. The overrunning clutch, which is built in as a part of the starter drive unit, uses steel balls or rollers installed in tapered notches. SEE FIGURE 52–23. This taper forces the balls or rollers tightly into the notch, when rotating in the direction necessary to start the engine. When the engine rotates faster than the starter pinion, the balls or rollers are forced out of the narrow tapered notch, allowing the pinion gear to turn freely (overrun). The spring between the drive tang or pulley and the overrunning clutch and pinion is called a mesh spring. It helps to cushion and control the engagement of the starter drive pinion with the engine flywheel gear. This spring is also called a compression spring, because the starter solenoid or starter yoke compresses the spring and the spring tension causes the starter pinion to engage the engine flywheel.
FAILURE MODE A starter drive is generally a dependable unit and does not require replacement unless defective or worn. The major wear occurs in the overrunning clutch section of the starter drive unit. The steel balls or rollers wear and often do not wedge tightly into the tapered notches as is necessary for engine cranking. A worn starter drive can cause the starter motor to operate and then stop cranking the engine and creating a “whining” noise. The whine indicates that the starter motor is operating and that the starter drive is not rotating the engine flywheel. The entire starter drive is replaced
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NEUTRAL SAFETY SWITCH
MOVABLE POLE SHOE DRIVE COIL
CONTACT POINTS
PIVOT PIN RETURN SPRING IGNITION SWITCH
HOLD-IN WINDING
DRIVE END BEARING
PLUNGER
S
FUSIBLE LINK B
SHIFT LEVER
M
TO BATTERY POSITIVE ()
PULL-IN WINDING CONTACT DISK
ARMATURE DRIVE YOKE OVERRUNNING CLUTCH
ARMATURE SHAFT STARTER DRIVE PINION
FIGURE 52–24 A Ford movable pole shoe starter. as a unit. The overrunning clutch section of the starter drive cannot be serviced or repaired separately because the drive is a sealed unit. Starter drives are most likely to fail intermittently at first and then more frequently, until replacement becomes necessary to start the engine. Intermittent starter drive failure (starter whine) is often most noticeable during cold weather.
POSITIVE ENGAGEMENT STARTERS
STARTER DRIVE ASSEMBLY
FIGURE 52–25 Wiring diagram of a typical starter solenoid. Notice that both the pull-in winding and the hold-in winding are energized when the ignition switch is first turned to the “start” position. As soon as the solenoid contact disk makes electrical contact with both the B and M terminals, the battery current is conducted to the starter motor and electrically neutralizes the pull-in winding.
opening, the starter will “clunk” the starter drive into engagement but will not allow the starter motor to operate.
SOLENOID-OPERATED STARTERS
OPERATION
Positive engagement starters (direct drive) were used on Ford engines from 1973 to 1990. These starters use the shunt coil winding and a movable pole shoe to engage the starter drive. The high starting current is controlled by an ignition switch– operated starter solenoid, usually mounted near the positive post of the battery. When this control circuit is closed, current flows through a hollow coil (called a drive coil) that attracts a movable pole shoe. As soon as the starter drive has engaged the engine flywheel, a tang on the movable pole shoe “opens” a set of contact points. The contact points provide the ground return path for the drive coil operation. After these grounding contacts are opened, all of the starter current can flow through the remaining three field coils and through the brushes to the armature, causing the starter to operate. The movable pole shoe is held down (which keeps the starter drive engaged) by a smaller coil on the inside of the main drive coil. This coil, called the holding coil, is strong enough to hold the starter drive engaged while permitting the flow of the maximum possible current to operate the starter. SEE FIGURE 52–24.
ADVANTAGES The movable metal pole shoe is attached to and engages the starter drive with a lever (called the plunger lever). As a result, this type of starter does not use a solenoid to engage the starter drive. DISADVANTAGES If the grounding contact points are severely pitted, the starter may not operate the starter drive or the starter motor because of the resulting poor ground for the drive coil. If the contact points are bent or damaged enough to prevent them from
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SOLENOID OPERATION A starter solenoid is an electromagnetic switch containing two separate, but connected, electromagnetic windings. This switch is used to engage the starter drive and control the current from the battery to the starter motor. SOLENOID WINDINGS The two internal windings contain approximately the same number of turns but are made from differentgauge wire. Both windings together produce a strong magnetic field that pulls a metal plunger into the solenoid. The plunger is attached to the starter drive through a shift fork lever. When the ignition switch is turned to the start position, the motion of the plunger into the solenoid causes the starter drive to move into mesh with the flywheel ring gear. 1. The heavier-gauge winding (called the pull-in winding) is needed to draw the plunger into the solenoid and is grounded through the starter motor. 2. The lighter-gauge winding (called the hold-in winding), which is grounded through the starter frame, produces enough magnetic force to keep the plunger in position. The main purpose of using two separate windings is to permit as much current as possible to operate the starter and yet provide the strong magnetic field required to move the starter drive into engagement. SEE FIGURE 52–25.
OPERATION 1. The solenoid operates as soon as the ignition or computercontrolled relay energizes the “S” (start) terminals. At that
?
FREQUENTLY ASKED QUESTION
How Are Starters Made So Small? Starters and most components in a vehicle are being made as small and as light in weight as possible to help increase vehicle performance and fuel economy. A starter can be constructed smaller due to the use of gear reduction and permanent magnets to achieve the same cranking torque as a straight drive starter, but using much smaller components. SEE FIGURE 52–26 for an example of an automotive starter armature that is palm size.
instant, the plunger is drawn into the solenoid enough to engage the starter drive. 2. The plunger makes contact with a metal disk that connects the battery terminal post of the solenoid to the motor terminal. This permits full battery current to flow through the solenoid to operate the starter motor. 3. The contact disk also electrically disconnects the pull-in winding. The solenoid has to work to supply current to the starter.
FIGURE 52–26 A palm-size starter armature. Therefore, if the starter motor operates at all, the solenoid is working, even though it may have high external resistance that could cause slow starter motor operation.
REVIEW QUESTIONS 1. What is the difference between the control circuit and the power (motor) circuit sections of a typical cranking circuit?
3. Why does a gear-reduction unit reduce the amount of current required by the starter motor?
2. What are the parts of a typical starter?
4. What are the symptoms of a defective starter drive?
CHAPTER QUIZ 1. Starter motors operate on the principle that ______________. a. The field coils rotate in the opposite direction from the armature b. Opposite magnetic poles repel c. Like magnetic poles repel d. The armature rotates from a strong magnetic field toward a weaker magnetic field 2. Series-wound electric motors ______________. a. Produce electrical power b. Produce maximum power at 0 RPM c. Produce maximum power at high RPM d. Use a shunt coil 3. Technician A says that a defective solenoid can cause a starter whine. Technician B says that a defective starter drive can cause a starter whining noise. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 4. The neutral safety switch is located ______________. a. Between the starter solenoid and the starter motor b. Inside the ignition switch itself c. Between the ignition switch and the starter solenoid d. In the battery cable between the battery and the starter solenoid
5. The brushes are used to transfer electrical power between ______________. a. Field coils and the armature b. The commutator segments c. The solenoid and the field coils d. The armature and the solenoid 6. The faster a starter motor rotates, ______________. a. The more current it draws from the battery b. The less CEMF is generated c. The less current it draws from the battery d. The greater the amount of torque produced 7. Normal cranking speed of the engine is about ______________. a. 2000 RPM c. 1000 RPM b. 1500 RPM d. 200 RPM 8. A starter motor rotates about ______________ times faster than the engine. a. 18 c. 5 b. 10 d. 2 9. Permanent magnets are commonly used for what part of the starter? a. Armature c. Field coils b. Solenoid d. Commutator 10. What unit contains a hold-in winding and a pull-in winding? a. Field coil c. Armature b. Starter solenoid d. Ignition switch
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chapter
53
CRANKING SYSTEM DIAGNOSIS AND SERVICE
OBJECTIVES: After studying Chapter 53, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “C” (Starting System Diagnosis and Repair). • Explain how to disassemble and reassemble a starter motor and solenoid. • Discuss how to perform a voltage drop test on the cranking circuit. • Describe how to perform cranking system repair procedures. • Describe testing and repair procedures of the cranking circuit and components. KEY TERMS: Bench testing 571 • Growler 571 • Shims 572 • Voltage drop 566
STARTING SYSTEM TROUBLESHOOTING PROCEDURE OVERVIEW
The proper operation of the starting system depends on a good battery, good cables and connections, and a good starter motor. Because a starting problem can be caused by a defective component anywhere in the starting circuit, it is important to check for the proper operation of each part of the circuit to diagnose and repair the problem quickly.
STEPS INVOLVED Following are the steps involved in the diagnosis of a fault in the cranking circuit. STEP 1
Verify the customer concern. Sometimes the customer is not aware of how the cranking system is supposed to work, especially if it is computer controlled.
STEP 2
Visually inspect the battery and battery connections. The starter is the highest amperage draw device used in a vehicle and any faults, such as corrosion on battery terminals, can cause cranking system problems.
STEP 3
Test battery condition. Perform a battery load or conductance test on the battery to be sure that the battery is capable of supplying the necessary current for the starter.
STEP 4
Check the control circuit. An open or high resistance anywhere in the control circuit can cause the starter motor to not engage. Items to check include: “S” terminal of the starter solenoid Neutral safety or clutch switch Starter enable relay (if equipped) Antitheft system fault (If the engine does not crank or start and the theft indicator light is on or flashing, there is likely a fault in the theft deterrent system. Check service information for the exact procedures to follow before attempting to service the cranking circuit. SEE FIGURE 53–1.)
STEP 5
Check voltage drop of the starter circuit. Any high resistance in either the power side or ground side of the starter circuit will cause the starter to rotate slowly or not at all.
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CHAPTER 5 3
THEFT DETERRENT INDICATOR LAMP
FIGURE 53–1 A theft deterrent indicator lamp on the dash. A flashing lamp usually indicates a fault in the system, and the engine may not start.
VOLTAGE DROP TESTING PURPOSE Voltage drop is the drop in voltage that occurs when current is flowing through a resistance. For example, a voltage drop is the difference between voltage at the source and voltage at the electrical device to which it is flowing. The higher the voltage drop is, the greater the resistance in the circuit. Even though voltage drop testing can be performed on any electrical circuit, the most common areas of testing include the cranking circuit and the charging circuit wiring and connections. Voltage drop testing should be performed on both the power side and ground side of the circuit. A high voltage drop (high resistance) in the cranking circuit wiring can cause slow engine cranking with less than normal starter amperage drain as a result of the excessive circuit resistance. If the voltage drop is high enough, such as that caused by dirty battery terminals, the starter may not operate. A typical symptom of high resistance in the cranking circuit is a “clicking” of the starter solenoid.
DIGITAL MULTIMETER
DIGITAL MULTIMETER
RECORD
MAX MIN
MAX MIN
RECORD
% HZ
%
0 1 2 3 4 5 6 7 8
HZ
0 1 2 3 4 5 6 7 8
9 0
9 0
MIN MAX MIN MAX HZ HZ
mV mV V
mA A
V
mA A
A
V A
V
A A
mA A
COM
mA A
COM
V
V
DIGITAL MULTIMETER RECORD
MAX MIN
% HZ
0 1 2 3 4 5 6 7 8
9 0
MIN MAX
HZ
mV mA A
V
A
V
A
mA A
COM
V
SOLENOID B S
BATTERY
STARTER
FIGURE 53–2 Voltmeter hookups for voltage drop testing of a solenoid-type cranking circuit.
TECH TIP
TECH TIP
Voltage Drop Is Resistance
A Warm Cable Equals High Resistance
Many technicians have asked, “Why measure voltage drop when the resistance can be easily measured using an ohmmeter?” Think of a battery cable with all the strands of the cable broken, except for one strand. If an ohmmeter were used to measure the resistance of the cable, the reading would be very low, probably less than 1 ohm. However, the cable is not capable of conducting the amount of current necessary to crank the engine. In less severe cases, several strands can be broken, thereby affecting the operation of the starter motor. Although the resistance of the battery cable will not indicate an increase, the restriction to current flow will cause heat and a drop of voltage available at the starter. Because resistance is not effective until current flows, measuring the voltage drop (differences in voltage between two points) is the most accurate method of determining the true resistance in a circuit. How much is too much? According to Bosch Corporation, all electrical circuits should have a maximum of 3% loss of the circuit voltage to resistance. Therefore, in a 12 volt circuit, the maximum loss of voltage in cables and connections should be 0.36 volt (12 ⫻ 0.03 ⫽ 0.36 volt). The remaining 97% of the circuit voltage (11.64 volts) is available to operate the electrical device (load). Just remember:
If a cable or connection is warm to the touch, there is electrical resistance in the cable or connection. The resistance changes electrical energy into heat energy. Therefore, if a voltmeter is not available, touch the battery cables and connections while cranking the engine. If any cable or connection is hot to the touch, it should be cleaned or replaced.
NOTE: Before a difference in voltage (voltage drop) can be measured between the ends of a battery cable, current must be flowing through the cable. Resistance is not effective unless current is flowing. If the engine is not being cranked, current is not flowing through the battery cables and the voltage drop cannot be measured. STEP 1
CAUTION: Never disconnect the high-voltage ignition wires unless they are connected to ground. The high voltage that could occur when cranking can cause the ignition coil to fail (arc internally).
• Low-voltage drop ⫽ Low resistance • High-voltage drop ⫽ High resistance
STEP 2
Connect one lead of the voltmeter to the starter motor battery terminal and the other end to the positive battery terminal.
STEP 3
Crank the engine and observe the reading while cranking. (Disregard the first higher reading.) The reading should be less than 0.20 volt (200 mV).
TEST PROCEDURE
Voltage drop testing of the wire involves connecting a voltmeter set to read DC volts to the suspected high-resistance cable ends and cranking the engine. SEE FIGURES 53–2 THROUGH 53–4.
Disable the ignition or fuel injection as follows: Disconnect the primary (low-voltage) electrical connection(s) from the ignition module or ignition coils. Remove the fuel-injection fuse or relay, or the electrical connection leading to all of the fuel injectors.
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DIGITAL MULTIMETER RECORD
MAX MIN
% HZ
0 1 2 3 4 5 6 7 8
9 0
MIN MAX
HZ
mV mA A
V
A
V
A
mA A
COM
V
DIGITAL MULTIMETER
DIGITAL MULTIMETER RECORD
RECORD
MAX MIN
MAX MIN
% HZ
%
0 1 2 3 4 5 6 7 8
HZ
0 1 2 3 4 5 6 7 8
9 0
S
9 0
R MIN MAX
MIN MAX HZ HZ
mV mV
mA A
V
mA A
V
A
V A
V
SOLENOID A A
mA A
COM
mA A
COM
V
V
DIGITAL MULTIMETER RECORD
MAX MIN
% HZ
0 1 2 3 4 5 6 7 8
9 0
MIN MAX
HZ
mV mA A
V
A
V
A
mA A
COM
V
BATTERY
STARTER
FIGURE 53–3 Voltmeter hookups for voltage drop testing of a Ford cranking circuit.
battery terminal and the other at the starter housing. Crank the engine and observe the voltmeter display. The voltage drop should be less than 0.2 volt (200 mV).
CONTROL CIRCUIT TESTING
FIGURE 53–4 To test the voltage drop of the battery cable connection, place one voltmeter lead on the battery terminal and the other voltmeter lead on the cable end and crank the engine. The voltmeter will read the difference in voltage between the two leads, which should not exceed 0.20 volt (200 mV).
STEP 4
STEP 5
568
If accessible, test the voltage drop across the “B” and “M” terminals of the starter solenoid with the engine cranking. The voltage drop should be less than 0.20 volt (200 mV). Repeat the voltage drop on the ground side of the cranking circuit by connecting one voltmeter lead to the negative
CHAPTER 5 3
PARTS INVOLVED The control circuit for the starting circuit includes the battery, ignition switch, neutral or clutch safety switch, theft deterrent system, and starter solenoid. When the ignition switch is rotated to the start position, current flows through the ignition switch and neutral safety switch to activate the solenoid. High current then flows directly from the battery through the solenoid and to the starter motor. Therefore, an open or break anywhere in the control circuit will prevent the operation of the starter motor. If a starter is inoperative, first check for voltage at the “S” (start) terminal of the starter solenoid. Check for faults with the following:
Neutral safety or clutch switch
Blown crank fuse
Open at the ignition switch in the crank position
Some models with antitheft controls use a relay to open this control circuit to prevent starter operation.
BATTERY CABLE SOLENOID
VAT
AMP PROBE "S" (START) TERMINAL WIRE
FIGURE 53–5 A starter amperage tester uses an amp probe around the positive or negative battery cables.
TECH TIP Watch the Dome Light When diagnosing any starter-related problem, open the door of the vehicle and observe the brightness of the dome or interior light(s). The brightness of any electrical lamp is proportional to the voltage of the battery. Normal operation of the starter results in a slight dimming of the dome light. If the light remains bright, the problem is usually an open in the control circuit. If the light goes out or almost goes out, there could be a problem with the following:
A shorted or grounded armature of field coils inside the starter Loose or corroded battery connections or cables Weak or discharged battery
FIGURE 53–6 The starter is located under the intake manifold on this Cadillac Northstar engine.
they do not apply to starter testing on the vehicle. If exact specifications are not available, the following can be used as general maximum amperage draw specifications for testing a starter on the vehicle.
4-cylinder engines ⫽ 150 to 185 amperes (normally less than 100 A) at room temperature 6-cylinder engines ⫽ 160 to 200 amperes (normally less than 125 A) at room temperature 8-cylinder engines ⫽ 185 to 250 amperes (normally less than 150 A) at room temperature Excessive current draw may indicate one or more of the following:
1. Binding of starter armature as a result of worn bushings 2. Oil too thick (viscosity too high) for weather conditions 3. Shorted or grounded starter windings or cables 4. Tight or seized engine 5. Shorted starter motor (usually caused by fault with the field coils or armature)
High mechanical resistance ⫽ High starter amperage draw
High electrical resistance ⫽ Low starter amperage draw Lower amperage draw and slow or no cranking may indicate one or more of the following:
STARTER AMPERAGE TEST REASON FOR A STARTER AMPERAGE TEST
A starter should be tested to see if the reason for slow or no cranking is due to a fault with the starter motor or another problem. A voltage drop test is used to find out if the battery cables and connections are okay. A starter amperage draw test determines if the starter motor is the cause of a no or slow cranking concern.
TEST PREPARATION
Before performing a starter amperage test, be certain that the battery is sufficiently charged (75% or more) and capable of supplying adequate starting current. Connect a starter amperage tester following the tester’s instructions. SEE FIGURE 53–5. A starter amperage test should be performed when the starter fails to operate normally (is slow in cranking) or as part of a routine electrical system inspection.
SPECIFICTIONS
Some service manuals specify normal starter amperage for starter motors being tested on the vehicle; however, most service manuals only give the specifications for bench testing a starter without a load applied. These specifications are helpful in making certain that a repaired starter meets exact specifications, but
Dirty or corroded battery connections
High internal resistance in the battery cable(s)
High internal starter motor resistance
Poor ground connection between the starter motor and the engine block
STARTER REMOVAL PROCEDURE After testing has confirmed that a starter motor may need to be replaced, most vehicle manufacturers recommend the following general steps and procedures. STEP 1
Disconnect the negative battery cable.
STEP 2
Hoist the vehicle safely. NOTE: This step may not be necessary. Check service information for the specified procedure for the vehicle being serviced. Some starters are located under the intake manifold. SEE FIGURE 53–6.
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COMMUTATOR END FRAME GROUND BRUSH
THROUGHBOLT
BRUSH HOLDER
BEARING
INSULATED BRUSH
ARMATURE BEARING INSULATED BRUSH SOLENOID FIELD FRAME
BRUSH SPRING
GROUND BRUSH SHIFT LEVER
ARMATURE SUPPORT
DRIVE END FRAME DRIVE SHAFT
BEARING SHAFT SUPPORT
CLUTCH DRIVE BUSHING PIVOT PIN
FIGURE 53–7 An exploded view of a typical solenoid-operated starter.
STEP 3
Remove the starter retaining bolts and lower the starter to gain access to the wire(s) connection(s) on the starter.
STEP 4
Disconnect and label the wire(s) from the starter and remove the starter.
STEP 5
Inspect the flywheel (flexplate) for ring gear damage. Also check that the mounting holes are clean and the mounting flange is clean and smooth. Service as needed.
3
S
STARTER MOTOR SERVICE PURPOSE
Most starter motors are replaced as an assembly or not easily disassembled or serviced. However, some starters, especially on classic muscle or collector vehicles, can be serviced.
DISASSEMBLY PROCEDURE
Disassembly of a starter motor
usually includes the following steps. STEP 1
Remove the starter solenoid assembly.
STEP 2
Mark the location of the through bolts on the field housing to help align them during reassembly.
STEP 3
Remove the drive-end housing and then the armature assembly.
SEE FIGURE 53–7.
INSPECTION AND TESTING
The various parts should be inspected and tested to see if the components can be used to restore the starter to serviceable condition.
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1
M
2
FIGURE 53–8 GM solenoid ohmmeter check. The reading between 1 and 3 (S terminal and ground) should be 0.4 to 0.6 ohm (hold-in winding). The reading between 1 and 2 (S terminal and M terminal) should be 0.2 to 0.4 ohm (pull-in winding).
Solenoid. Check the resistance of the solenoid winding. The solenoid can be tested using an ohmmeter to check for the proper resistance in the hold-in and pull-in windings. SEE FIGURE 53–8.
Most technicians replace the solenoid whenever the starter is replaced and is usually included with a replacement starter.
Starter armature. After the starter drive has been removed from the armature, it can be checked for runout using a dial indicator and V-blocks, as shown in FIGURE 53–9.
DIAL INDICATOR
V-BLOCK
ARMATURE BRUSH
BRUSH ANGLE
V-BLOCK
FIGURE 53–9 Measuring an armature shaft for runout using a dial indicator and V-blocks.
Growler. Because the loops of copper wire are interconnected in the armature of a starter, an armature can be accurately tested only by use of a growler. A growler is a 110 volt AC test unit that generates an alternating (60 hertz) magnetic field around an armature. A starter armature is placed into the V-shaped top portion of a laminated soft-iron core surrounded by a coil of copper wire. Plug the growler into a 110 volt outlet and then follow the instructions for testing the armature. Starter motor field coils. With the armature removed from the starter motor, the field coils should be tested for opens and grounds using a powered test light or an ohmmeter. To test for a grounded field coil, touch one lead of the tester to a field brush (insulated or hot) and the other end to the starter field housing. The ohmmeter should indicate infinity (no continuity), and the test light should not light. If there is continuity, replace the field coil housing assembly. The ground brushes should show continuity to the starter housing. NOTE: Many starters use removable field coils. These coils must be rewound using the proper equipment and insulating materials. Usually, the cost involved in replacing defective field coils exceeds the cost of a replacement starter.
Starter brush inspection. Starter brushes should be replaced if the brush length is less than half of its original length (less than 0.5 in. [13 mm]). On some models of starter motors, the field brushes are serviced with the field coil assembly and the ground brushes with the brush holder. Many starters use brushes that are held in with screws and are easily replaced, whereas other starters may require soldering to remove and replace the brushes. SEE FIGURE 53–10.
MICA INSULATION
COMMUTATOR
ROTATION
FIGURE 53–10 Replacement starter brushes should be installed so the beveled edge matches the rotation of the commutator.
STARTER INSTALLATION After verifying that the starter assembly is functioning correctly, verify that the negative battery cable has been disconnected. Then safely hoist the vehicle, if necessary. Following are the usual steps to install a starter. Be sure to check service information for the exact procedures to follow for the vehicle being serviced. STEP 1
Check service information for the exact wiring connections to the starter and/or solenoid.
STEP 2
Verify that all electrical connections on the starter motor and/or solenoid are correct for the vehicle and that they are in good condition. NOTE: Be sure that the locking nuts for the studs are tight. Often, the retaining nut that holds the wire to the stud will be properly tightened, but if the stud itself is loose, cranking problems can occur.
STEP 3
Attach the power and control wires.
STEP 4
Install the starter, and torque all the fasteners to factory specifications and tighten evenly.
STEP 5
Perform a starter amperage draw test and check for proper engine cranking. CAUTION: Be sure to install all factory heat shields to help ensure problem starter operation under all weather and driving conditions.
BENCH TESTING Every starter should be tested before installation in a vehicle. Bench testing is the usual method and involves clamping the starter in a vise to prevent rotation during operation and connecting heavygauge jumper wires (minimum 4 gauge) to both a battery known to be good and the starter. The starter motor should rotate as fast as specifications indicate and not draw more than the free-spinning amperage permitted. A typical amperage specification for a starter being tested on a bench (not installed in a vehicle) usually ranges from 60 to 100 amperes.
STARTER DRIVE-TOFLYWHEEL CLEARANCE NEED FOR SHIMS For the proper operation of the starter and absence of abnormal starter noise, there must be a slight clearance between the starter pinion and the engine flywheel ring gear. Many
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TECH TIP SHIM 1/2 SHIM
Reuse Drive-End Housing to Be Sure Most GM starter motors use a pad mount and attach to the engine with bolts through the drive-end (nose) housing. Many times when a starter is replaced on a GM vehicle, the starter makes noise because of improper starter pinion-to-engine flywheel ring gear clearance. Instead of spending a lot of time shimming the new starter, simply remove the drive-end housing from the original starter and install it on the replacement starter. Service the bushing in the drive-end housing if needed. Because the original starter did not produce excessive gear engagement noise, the replacement starter will also be okay. Reuse any shims that were used with the original starter. This is preferable to removing and reinstalling the replacement starter several times until the proper clearance is determined.
OUTSIDE MOUNTING PAD
FLYWHEEL
STEP 5 GAUGE TOOL
(1/8" DIAMETER DRILL BIT OR EQUAL)
If no shims have been used and the fit of the gauge tool is too loose, add a half shim to the outside pad only. This moves the starter closer to the teeth of the engine flywheel.
ARMATURE SHAFT
FIGURE 53–11 A shim (or half shim) may be needed to provide the proper clearance between the flywheel teeth of the engine and the pinion teeth of the starter.
starters use shims, which are thin metal strips between the flywheel and the engine block mounting pad to provide the proper clearance. SEE FIGURE 53–11. Some manufacturers use shims under the starter drive-end housings during production. Other manufacturers grind the mounting pads at the factory for proper starter pinion gear clearance. If a GM starter is replaced, the starter pinion should be checked and corrected as necessary to prevent starter damage and excessive noise.
STARTING SYSTEM SYMPTOM GUIDE The following list will assist technicians in troubleshooting starting systems. Problem 1. Starter motor whines
2.
SYMPTOMS OF CLEARANCE PROBLEMS
If the clearance is too great, the starter will produce a highpitched whine during cranking.
If the clearance is too small, the starter may bind, crank slowly, or produce a high-pitched whine after the engine starts, just as the ignition key is released.
3.
PROCEDURE FOR PROPER CLEARANCE
To be sure that the starter is shimmed correctly, use the following procedure. STEP 1
Place the starter in position and finger-tighten the mounting bolts.
STEP 2
Use a 1/8 in. diameter drill bit (or gauge tool) and insert between the armature shaft and a tooth of the engine flywheel.
STEP 3
If the gauge tool cannot be inserted, use a full-length shim across both mounting holes to move the starter away from the flywheel.
STEP 4
Remove a shim (or shims) if the gauge tool is loose between the shaft and the tooth of the engine flywheel.
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4.
5.
Possible Causes 1. Possible defective starter drive; worn starter drive engagement yoke; defective flywheel; improper starter drive to flywheel clearance Starter rotates 2. Possible high resistance in the batslowly tery cables or connections; possible defective or discharged battery; possible worn starter bushings, causing the starter armature to drag on the field coils; possible worn starter brushes or weak brush springs; possible defective (open or shorted) field coil Starter fails to 3. Possible defective ignition switch or rotate neutral safety switch, or open in the starter motor control circuit; theft deterrent system fault; possible defective starter solenoid Starter produces 4. Possible defective starter drive unit; grinding noise possible defective flywheel; possible incorrect distance between the starter pinion and the flywheel; possible cracked or broken starter drive-end housing; worn or damaged flywheel or ring gear teeth Starter clicks when 5. Low battery voltage; loose or corroded engaged battery connections
STARTER OVERHAUL
1
3
5
This dirty and greasy starter can be restored to useful service.
An old starter field housing is being used to support the drive-end housing of the starter as it is being disassembled. This rebuilder is using an electric impact wrench to remove the solenoid fasteners.
After the retaining screws have been removed, the solenoid can be separated from the starter motor. This rebuilder always replaces the solenoid.
2
The connecting wire between the solenoid and the starter is removed.
4
A Torx driver is used to remove the solenoid attaching screws.
6
The through-bolts are being removed.
CONTINUED
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STARTER OVERHAUL
7
9
The brush end plate is removed.
Notice that the length of a direct-drive starter armature (top) is the same length as the overall length of a gearreduction armature except smaller in diameter.
11 574
(CONTINUED)
This figure shows the planetary ring gear and pinion gears.
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8
The armature assembly is removed from the field frame.
10
A light tap with a hammer dislodges the armature thrust ball (in the palm of the hand) from the center of the gear reduction assembly.
12
A close-up of one of the planetary gears, which shows the small needle bearings on the inside.
STEP-BY-STEP
13
The clip is removed from the shaft so the planetary gear assembly can be separated and inspected.
14
15
The commutator on the armature is discolored and the brushes may not have been making good contact with the segments.
16
17
The finished commutator looks like new.
18
The shaft assembly is being separated from the stationary gear assembly.
All of the starter components are placed in a tumbler with water-based cleaner. The armature is installed in a lathe and the commutator is resurfaced using emery cloth.
Starter reassembly begins by installing a new starter drive on the shaft assembly. The stop ring and stop ring retainer are then installed.
CONTINUED
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STARTER OVERHAUL
(CONTINUED)
19
The gear-reduction assembly is positioned along with the shift fork (drive lever) into the cleaned drive-end housing.
20
After gear retainer has been installed over the gear reduction assembly, the armature is installed.
21
New brushes are being installed into the brush holder assembly.
22
The brush end plate and the through-bolts are installed, being sure that the ground connection for the brushes is clean and tight.
23 576
This starter was restored to useful service by replacing the solenoid, the brushes, and the starter drive assembly plus a thorough cleaning and attention to detail in the reassembly.
CHAPTER 53
REVIEW QUESTIONS 1. What are the parts of the cranking circuit?
3. What are the steps necessary to replace a starter?
2. What are the steps taken to perform a voltage drop test of the cranking circuit?
CHAPTER QUIZ 1. A growler is used to test what starter component? a. Field coils c. Commutator b. Armatures d. Solenoid 2. Two technicians are discussing what could be the cause of slow cranking and excessive current draw. Technician A says that an engine mechanical fault could be the cause. Technician B says that the starter motor could be binding or defective. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 3. A V-6 is being checked for starter amperage draw. The initial surge current was about 210 amperes and about 160 amperes during cranking. Technician A says the starter is defective and should be replaced because the current flow exceeds 200 amperes. Technician B says this is normal current draw for a starter motor on a V-6 engine. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 4. What component or circuit can keep the engine from cranking? a. Antitheft c. Ignition switch b. Solenoid d. All of the above 5. Technician A says that a discharged battery (lower than normal battery voltage) can cause solenoid clicking. Technician B says that a discharged battery or dirty (corroded) battery cables can cause solenoid clicking. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 6. Slow cranking by the starter can be caused by all except __________. a. A low or discharged battery b. Corroded or dirty battery cables c. Engine mechanical problems d. An open neutral safety switch
chapter
7. Bench testing of a starter should be done ______________. a. After reassembling an old starter b. Before installing a new starter c. After removing the old starter d. Both a and b 8. If the clearance between the starter pinion and the engine flywheel is too great, ______________. a. The starter will produce a high-pitched whine during cranking b. The starter will produce a high-pitched whine after the engine starts c. The starter drive will not rotate at all d. The solenoid will not engage the starter drive unit 9. A technician connects one lead of a digital voltmeter to the positive (1) terminal of the battery and the other meter lead to the battery terminal (B) of the starter solenoid and then cranks the engine. During cranking, the voltmeter displays a reading of 878 mV. Technician A says that this reading indicates that the positive battery cable has too high resistance. Technician B says that this reading indicates that the starter is defective. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 10. A vehicle equipped with a V-8 engine does not crank fast enough to start. Technician A says the battery could be discharged or defective. Technician B says that the negative cable could be loose at the battery. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
CHARGING SYSTEM
54 OBJECTIVES: After studying Chapter 54, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “D” (Charging System Diagnosis and Repair). • List the parts of a typical alternator. • Describe how an alternator works. • Explain how the powertrain control module (PCM) controls the charging circuit. KEY TERMS: Alternator 578 • Claw poles 580 • Delta winding 583 • Diodes 580 • Drive-end (DE) housing 578 • Duty cycle 585 • EPM 585 • IDP 578 • OAD 578 • OAP 578 • Rectifier 581 • Rotor 579 • Slip-ring-end (SRE) housing 578 • Stator 580 • Thermistor 585
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PRINCIPLES OF ALTERNATOR OPERATION TERMINOLOGY It is the purpose and function of the charging system to keep the battery fully charged. The Society of Automotive Engineers (SAE) term for the unit that generates electricity is generator. The term alternator is most commonly used in the trade and will be used in this title. PRINCIPLES
All electrical alternators use the principle of electromagnetic induction to generate electrical power from mechanical power. Electromagnetic induction involves the generation of an electrical current in a conductor when the conductor is moved through a magnetic field. The amount of current generated can be increased by the following factors.
FIGURE 54–1 A typical alternator on a Chevrolet V-8 engine.
1. Increasing the speed of the conductors through the magnetic field 2. Increasing the number of conductors passing through the magnetic field
SLIP-RING-END HOUSING
3. Increasing the strength of the magnetic field
DRIVEEND HOUSING
CHANGING AC TO DC
An alternator generates an alternating current (AC) because the current changes polarity during the alternator’s rotation. However, a battery cannot “store” alternating current; therefore, this alternating current is changed to direct current (DC) by diodes inside the alternator. Diodes are one-way electrical check valves that permit current to flow in only one direction.
ALTERNATOR CONSTRUCTION
STATOR
HOUSING
An alternator is constructed using a two-piece cast aluminum housing. Aluminum is used because of its lightweight, nonmagnetic properties and heat transfer properties needed to help keep the alternator cool. A front ball bearing is pressed into the front housing, called the drive-end (DE) housing, to provide the support and friction reduction necessary for the belt-driven rotor assembly. The rear housing, or the slip-ring-end (SRE) housing, usually contains either a roller bearing or ball bearing support for the rotor and mounting for the brushes, diodes, and internal voltage regulator (if so equipped). SEE FIGURES 54–1 AND 54–2.
ALTERNATOR OVERRUNNING PULLEYS PURPOSE AND FUNCTION
Many alternators are equipped with an overrunning alternator pulley (OAP), also called an overrunning clutch pulley or an alternator clutch pulley. The purpose of this pulley is to help eliminate noise and vibration in the accessory drive belt system, especially when the engine is at idle speed. At idle, engine impulses are transmitted to the alternator through the accessory drive belt. The mass of the rotor of the alternator tends
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FIGURE 54–2 The end frame toward the drive belt is called the drive-end housing and the rear section is called the slip-ring-end housing.
to want to keep spinning, but the engine crankshaft speeds up and slows down slightly due to the power impulses. Using a one-way clutch in the alternator pulley allows the belt to apply power to the alternator in only one direction, thereby reducing fluctuations in the belt. SEE FIGURES 54–3 AND 54–4. A conventional drive pulley attaches to the alternator (rotor) shaft with a nut and lock washer. In the overrunning clutch pulley, the inner race of the clutch acts as the nut as it screws on to the shaft. Special tools are required to remove and install this type of pulley. Another type of alternator pulley uses a dampener spring inside, plus a one-way clutch. These units have the following names.
Isolating Decoupler Pulley (IDP)
Active Alternator Pulley (AAP)
Alternator Decoupler Pulley (ADP)
Alternator Overrunning Decoupler Pulley
Overrunning Alternator Dampener (OAD) (most common term)
TECH TIP Alternator Horsepower and Engine Operation Many technicians are asked how much power certain accessories require. A 100 ampere alternator requires about 2 horsepower from the engine. One horsepower is equal to 746 watts. Watts are calculated by multiplying amperes times volts. Power in watts ⫽ 100 A ⫻ 14.5 V ⫽ 1,450 W 1 hp ⫽ 746 W
FIGURE 54–3 An OAP on a Chevrolet Corvette alternator.
BEARINGS
CLUTCH
Therefore, 1,450 watts is about 2 horsepower. Allowing about 20% for mechanical and electrical losses adds another 0.4 horsepower. Therefore, when someone asks how much power it takes to produce 100 amperes from an alternator, the answer is 2.4 horsepower. Many alternators delay the electrical load to prevent the engine from stumbling when a heavy electrical load is applied. The voltage regulator or vehicle computer is capable of gradually increasing the output of the alternator over a period of several minutes. Even though 2 horsepower does not sound like much, a sudden demand for 2 horsepower from an idling engine can cause the engine to run rough or stall. The difference in part numbers of various alternators is often an indication of the time interval over which the load is applied. Therefore, using the wrong replacement alternator could cause the engine to stall!
? CENTER HUB
FREQUENTLY ASKED QUESTION
Can I Install an OAP or an OAD to My Alternator? OUTER HUB
OVERUNNING ALTERNATOR PULLEY (OAP)
FIGURE 54–4 An exploded view of an overrunning alternator pulley showing all of the internal parts.
Usually, no. An alternator needs to be equipped with the proper shaft to allow the installation of an OAP or OAD. This also means that a conventional pulley often cannot be used to replace a defective overrunning alternator pulley or dampener with a conventional pulley. Check service information for the exact procedure to follow.
OAP or OAD pulleys are primarily used on vehicles equipped with diesel engines or on luxury vehicles where noise and vibration need to be kept at a minimum. Both are designed to:
Reduce accessory drive belt noise
Improve the life of the accessory drive belt
Improve fuel economy by allowing the engine to be operated at a low idle speed
ALTERNATOR COMPONENTS AND OPERATION ROTOR CONSTRUCTION
The rotor is the rotating part of the alternator and is driven by the accessory drive belt. The rotor creates the magnetic field of the alternator and produces a current by
TECH TIP Always Check the OAP or OAD First Overrunning alternator pulleys and overrunning alternator dampeners can fail. The most common factor is the one-way clutch. If it fails, it can freewheel and not power the alternator or it can lock up and not provide the dampening as designed. If the charging system is not working, the OAP or OAD could be the cause, rather than a fault in the alternator itself. In most cases, the entire alternator assembly will be replaced because each OAP or OAD is unique for each application and both require special tools to remove and replace. SEE FIGURE 54–5.
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OVERUNNING ALTERNATOR PULLEY (OAP)
MAGNETIC LINES OF FORCE
N S
N
S
N
ROTOR ASSEMBLY Y
SLIP RINGS
S ROTOR WINDINGS (ALTERNATOR FIELD)
FIGURE 54–5 A special tool is needed to remove and install overrunning alternator pulleys or dampeners.
FIGURE 54–7 Rotor assembly of a typical alternator. Current through the slip rings causes the “fingers” of the rotor to become alternating north and south magnetic poles. As the rotor revolves, these magnetic lines of force induce a current in the stator windings.
INTERNAL COOLING FAN
ROTOR POLES
FRONT BEARING
DRIVE PULLEY
FIGURE 54–6 A cutaway of an alternator, showing the rotor and cooling fan that is used to force air through the unit to remove the heat created when it is charging the battery and supplying electrical power for the vehicle.
electromagnetic induction in the stationary stator windings. The rotor is constructed of many turns of copper wire coated with a varnish insulation wound over an iron core. The iron core is attached to the rotor shaft. At both ends of the rotor windings are heavy-gauge metal plates bent over the windings with triangular fingers called claw poles. These pole fingers do not touch, but alternate or interlace, as shown in FIGURE 54–6.
HOW ROTORS CREATE MAGNETIC FIELDS
The two ends of the rotor winding are connected to the rotor’s slip rings. Current for the rotor flows from the battery into one brush that rides on one of the slip rings, then flows through the rotor winding, then exits the rotor through the other slip ring and brush. One alternator brush is considered to be the “positive” brush and one is considered to be the “negative” or “ground” brush. The voltage regulator is connected to either the positive or the negative brush and controls the field current through the rotor that controls the output of the alternator.
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If current flows through the rotor windings, the metal pole pieces at each end of the rotor become electromagnets. Whether a north or a south pole magnet is created depends on the direction in which the wire coil is wound. Because the pole pieces are attached to each end of the rotor, one pole piece will be a north pole magnet. The other pole piece is on the opposite end of the rotor and therefore is viewed as being wound in the opposite direction, creating a south pole. Therefore, the rotor fingers are alternating north and south magnetic poles. The magnetic fields are created between the alternating pole piece fingers. These individual magnetic fields produce a current by electromagnetic induction in the stationary stator windings. SEE FIGURE 54–7.
ROTOR CURRENT The current necessary for the field (rotor) windings is conducted through slip rings with carbon brushes. The maximum rated alternator output in amperes depends on the number and gauge of the rotor windings. Substituting rotors from one alternator to another can greatly affect maximum output. Many commercially rebuilt alternators are tested and then display a sticker to indicate their tested output. The original rating stamped on the housing is then ground off. The current for the field is controlled by the voltage regulator and is conducted to the slip rings through carbon brushes. The brushes conduct only the field current which is usually between 2 and 5 amperes. STATOR CONSTRUCTION
The stator consists of the stationary coil windings inside the alternator. The stator is supported between the two halves of the alternator housing, with three copper wire windings that are wound on a laminated metal core. As the rotor revolves, its moving magnetic field induces a current in the stator windings. SEE FIGURE 54–8.
DIODES Diodes are constructed of a semiconductor material (usually silicon) and operate as a one-way electrical check valve that permits the current to flow in only one direction. Alternators often
STATOR
ROTOR DRIVE END FRAME
RETAINER BEARING
DRIVE PULLEY
FAN GUIDE
REAR END FRAME DIODE ASSEMBLY REGULATOR
FIGURE 54–8 An exploded view of a typical alternator showing all of its internal parts including the stator windings.
A
S N
B
LOAD CIRCUIT
FIGURE 54–9 A rectifier usually includes six diodes in one assembly and is used to rectify AC voltage from the stator windings into DC voltage suitable for use by the battery and electrical devices in the vehicle. use six diodes (one positive and one negative set for each of the three stator windings) to convert alternating current to direct current. Diodes used in alternators are included in a single part called a rectifier, or rectifier bridge. A rectifier not only includes the diodes (usually six), but also the cooling fins and connections for the stator windings and the voltage regulator. SEE FIGURE 54–9.
DIODE TRIO
Some alternators are equipped with a diode trio that supplies current to the brushes from the stator windings. A diode trio uses three diodes, in one housing, with one diode for each of the three stator windings and then one output terminal.
ROTATING MAGNETIC FIELD
FIGURE 54–10 Magnetic lines of force cutting across a conductor induce a voltage and current in the conductor.
HOW AN ALTERNATOR WORKS FIELD CURRENT IS PRODUCED A rotor inside an alternator is turned by a belt and drive pulley which are turned by the engine. The magnetic field of the rotor generates a current in the stator windings by electromagnetic induction. SEE FIGURE 54–10. Field current flowing through the slip rings to the rotor creates an alternating north and south pole on the rotor, with a magnetic field between each finger of the rotor. C H AR GIN G S Y S T EM
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3
4
5
6
7
8
9
N
N
N
N
N
N
N
VOLTMETER 0
S
S
S
S
S
S
S
S
180°
225°
270°
315°
360°
S
N
S
VOLTAGE
2 N
1 N
SINE-WAVE 0
BRUSHES SLIP RINGS
0°
45°
90°
135°
DEGREES OF ROTOR ROTATION
FIGURE 54–11 A sine wave (shaped like the letter S on its side) voltage curve is created by one revolution of a winding as it rotates in a magnetic field.
A
B
C
N
S
VOLTAGE U
0
0°
90°
180°
270°
360°
DEGREES OF ROTOR ROTATION
FIGURE 54–12 When three windings (A, B, and C) are present in a stator, the resulting current generation is represented by the three sine waves. The voltages are 120 degrees out of phase. The connection of the individual phases produces a three-phase alternating voltage. WYE (Y) WOUND STATOR
CURRENT IS INDUCED IN THE STATOR
The induced current in the stator windings is an alternating current because of the alternating magnetic field of the rotor. The induced current starts to increase as the magnetic field starts to induce current in each winding of the stator. The current then peaks when the magnetic field is the strongest and starts to decrease as the magnetic field moves away from the stator winding. Therefore, the current generated is described as being of a sine wave or alternating current pattern. SEE FIGURE 54–11. As the rotor continues to rotate, this sine wave current is induced in each of the three windings of the stator. Because each of the three windings generates a sine wave current, as shown in FIGURE 54–12, the resulting currents combine to form a three-phase voltage output. The current induced in the stator windings connects to diodes (one-way electrical check valves) that permit the alternator output current to flow in only one direction. All alternators contain six diodes, one pair (a positive and a negative diode) for each of the three stator windings. Some alternators contain eight diodes with another pair connected to the center connection of a wye-type stator.
WYE-CONNECTED STATORS The Y (pronounced “wye” and generally so written) type or star pattern is the most commonly used alternator stator winding connection. SEE FIGURE 54–13.
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STA TO () BATTERY
6-DIODE RECTIFIER
FIGURE 54–13 Wye-connected stator winding.
The output current with a wye-type stator connection is constant over a broad alternator speed range. Current is induced in each winding by electromagnetic induction from the rotating magnetic fields of the rotor. In a wye-type stator connection, the currents must combine because two windings are always connected in series. SEE FIGURE 54–14. The current produced in each winding is added to the other windings’ current and then flows through the diodes to the alternator output terminal. One-half of the current produced is available at the
DC OUTPUT
STATOR
6-DIODE RECTIFIER
BATTERY
FIGURE 54–14 As the magnetic field, created in the rotor, cuts across the windings of the stator, a current is induced. Notice that the current path includes passing through one positive (⫹) diode on the way to the battery and one negative (⫺) diode as a complete circuit is completed through the rectifier and stator.
FIGURE 54–16 A stator assembly with six, rather than the normal three, windings. faster than engine speed, depending on the relative pulley sizes used for the belt drive. For example, if an engine is operating at 5000 RPM, the alternator will be rotating at about 15,000 RPM.
DELTA () WOUND STATOR
TO () BATTERY
6-DIODE RECTIFIER
2. Number of conductors. A high-output alternator contains more turns of wire in the stator windings. Stator winding connections (whether wye or delta) also affect the maximum alternator output. SEE FIGURE 54–16 for an example of a stator that has six rather than three windings, which greatly increases the amperage output of the alternator. 3. Strength of the magnetic field. If the magnetic field is strong, a high output is possible because the current generated by electromagnetic induction is dependent on the number of magnetic lines of force that are cut. a. The strength of the magnetic field can be increased by increasing the number of turns of conductor wire wound on the rotor. A higher output alternator rotor has more turns of wire than an alternator rotor with a low rated output. b. The strength of the magnetic field also depends on the current through the field coil (rotor). Because magnetic field strength is measured in ampere-turns, the greater the amperage or the number of turns, or both, the greater the alternator output.
FIGURE 54–15 Delta-connected stator winding. neutral junction (usually labeled “STA” for stator). The voltage at this center point is used by some alternator manufacturers (especially Ford) to control the charge indicator light or is used by the voltage regulator to control the rotor field current.
DELTA-CONNECTED STATORS
The delta winding is connected in a triangular shape. Delta is a Greek letter shaped like a triangle. SEE FIGURE 54–15. Current induced in each winding flows to the diodes in a parallel circuit. More current can flow through two parallel circuits than can flow through a series circuit (as in a wye-type stator connection). Delta-connected stators are used on alternators where high output at high-alternator RPM is required. The delta-connected alternator can produce 73% more current than the same alternator with wye-type stator connections. For example, if an alternator with a wye-connected stator can produce 55 A, the same alternator with delta-connected stator windings can produce 73% more current, or 95 A (55 ⫻ 1.73 ⫽ 95). The delta-connected alternator, however, produces lower current at low speed and must be operated at high speed to produce its maximum output.
ALTERNATOR OUTPUT FACTORS
ALTERNATOR VOLTAGE REGULATION PRINCIPLES
An automotive alternator must be able to produce electrical pressure (voltage) higher than battery voltage to charge the battery. Excessively high voltage can damage the battery, electrical components, and the lights of a vehicle. Basic principles include the following:
If no (zero) amperes of current existed throughout the field coil of the alternator (rotor), alternator output would be zero because without field current a magnetic field does not exist.
The field current required by most automotive alternators is less than 3 amperes. It is the control of the field current that controls the output of the alternator.
Current for the rotor flows from the battery positive post, through the rotor positive brush, into the rotor field winding, and exits the rotor winding through the rotor ground brush. Most voltage regulators control field current by controlling the amount of field current through the ground brush.
The voltage regulator simply opens the field circuit if the voltage reaches a predetermined level, then closes the field
The output voltage and current of an alternator depend on the following factors. 1. Speed of rotation. Alternator output is increased with alternator rotational speed up to the alternator’s maximum possible ampere output. Alternators normally rotate at a speed two to three times
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IGNITION SWITCH
VOLTS
VOLTAGE RANGE 14.6 V
INDICATOR LAMP
14.2 V
BATTERY
BAT
40
REGULATOR SETTING
2
RPM
1
R2
DIODE TRIO
TR2
FIGURE 54–17 Typical voltage regulator range.
D2 D3 C1
REGULATOR BRUSHES
SLIP RINGS
C2
FIELD COIL (ROTOR)
FIGURE 54–18 A typical electronic voltage regulator with the cover removed showing the circuits inside.
STATOR
circuit again as necessary to maintain the correct charging voltage. SEE FIGURE 54–17.
The electronic circuit of the voltage regulator cycles between 10 and 7,000 times per second as needed to accurately control the field current through the rotor, and therefore control the alternator output.
REGULATOR OPERATION
The control of the field current is accomplished by opening and closing the ground side of the field circuit through the rotor on most alternators.
The zener diode is a major electronic component that makes voltage regulation possible. A zener diode blocks current flow until a specific voltage is reached, then it permits current to flow. Alternator voltage from the stator and diodes is first sent through a thermistor, which changes resistance with temperature, and then to a zener diode. When the upper-limit voltage is reached, the zener diode conducts current to a transistor, which then opens the field (rotor) circuit. The electronics are usually housed in a separate part inside the alternator. SEE FIGURES 54–18 AND 54–19.
BATTERY CONDITION AND CHARGING VOLTAGE If the automotive battery is discharged, its voltage will be lower than the voltage of a fully charged battery. The alternator will supply charging current, but it may not reach the maximum charging voltage. For example, if a vehicle is jump started and run at a fast idle (2,000 RPM), the charging voltage may be only 12 volts. In this case, the following may occur.
As the battery becomes charged and the battery voltage increases, the charging voltage will also increase, until the voltage regulator limit is reached.
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RECTIFIER BRIDGE
FIGURE 54–19 Typical General Motors SI-style alternator with an integral voltage regulator. Voltage present at terminal 2 is used to reverse bias the zener diode (D2) that controls TR2. The positive brush is fed by the ignition current (terminal I) plus current from the diode trio.
Then the voltage regulator will start to control the charging voltage. A good, but discharged, battery should be able to convert into chemical energy all the current the alternator can produce. As long as alternator voltage is higher than battery voltage, current will flow from the alternator (high voltage) to the battery (lower voltage).
Therefore, if a voltmeter is connected to a discharged battery with the engine running, it may indicate charging voltage that is lower than normally acceptable.
In other words, the condition and voltage of the battery do determine the charging rate of the alternator. It is often stated that the battery is the true “voltage regulator” and that the voltage regulator simply acts as the upper-limit voltage control. This is the reason why all charging system testing must be performed with a reliable and known to be good battery, at least 75% charged, to be assured of accurate test results. If a discharged battery is used during charging system testing, tests could mistakenly indicate a defective alternator and/ or voltage regulator and could cause the stator windings to overheat.
TEMPERATURE COMPENSATION
All voltage regulators (mechanical or electronic) provide a method for increasing the charging
COOLANT CONNECTIONS
CURRENT SENSOR
FIGURE 54–21 A Hall-effect current sensor attached to the positive battery cable is used as part of the EPM system. FIGURE 54–20 A coolant-cooled alternator showing the hose connections where coolant from the engine flows through the rear frame of the alternator. voltage slightly at low temperatures and for lowering the charging voltage at high temperatures. A battery requires a higher charging voltage at low temperatures because of the resistance to chemical reaction changes. However, the battery would be overcharged if the charging voltage were not reduced during warm weather. Electronic voltage regulators use a temperature-sensitive resistor in the regulator circuit. This resistor, called a thermistor, provides lower resistance as the temperature increases. A thermistor is used in the electronic circuits of the voltage regulator to control charging voltage over a wide range of underhood temperatures. NOTE: Voltmeter test results may vary according to temperature. Charging voltage tested at 32°F (0°C) will be higher than for the same vehicle tested at 80°F (27°C) because of the temperature-compensation factors built into voltage regulators.
ALTERNATOR COOLING Alternators create heat during normal operation and this heat must be removed to protect the components inside, especially the diodes and voltage regulator. The types of cooling include:
External fan
Internal fan(s)
Both an external fan and an internal fan
Coolant cooled ( SEE FIGURE 54–20.)
COMPUTER-CONTROLLED ALTERNATORS TYPES OF SYSTEMS
Computers can interface with the charg-
ing system in three ways. 1. The computer can activate the charging system by turning on and off the field current to the rotor. In other words, the computer, usually the powertrain control module (PCM), controls the field current to the rotor.
2. The computer can monitor the operation of the alternator and increase engine speed if needed during conditions when a heavy load is demanded by the alternator. 3. The computer can control the alternator by controlling alternator output to match the needs of the electrical system. This system detects the electrical needs of the vehicle and commands the alternator to charge only when needed to improve fuel economy.
GM ELECTRICAL POWER MANAGEMENT SYSTEM
A typical system used on some General Motors vehicles is called electrical power management (EPM). It uses a Hall-effect sensor attached to the negative or positive battery cable to measure the current leaving and entering the battery. SEE FIGURE 54–21. The engine control module (ECM) controls the alternator by changing the on-time of the current through the rotor. SEE FIGURE 54–22. The on-time, called duty cycle, varies from 5% to 95%. SEE CHART 54–1. This system has six modes of operation. 1. Charge mode. The charge mode is activated when any of the following occurs. Electric cooling fans are on high speed. Rear window defogger is on. Battery state of charge (SOC) is less than 80%. Outside (ambient) temperature is less than 32°F (0°C). 2. Fuel economy mode. This mode reduces the load on the engine from the alternator for maximum fuel economy. This mode is activated when the following conditions are met. Ambient temperature is above 32°F (0°C). The state of charge of the battery is 80% or higher. The cooling fans and rear defogger are off. The target voltage is 13 volts and will return to the charge mode, if needed. 3. Voltage reduction mode. This mode is commanded to reduce the stress on the battery during low-load conditions. This mode is activated when the following conditions are met. Ambient temperature is above 32°F (0°C). Battery discharge rate is less than 7 amperes. Rear defogger is off. Cooling fans are on low or off. Target voltage is limited to 12.7 volts.
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FIELD CURRENT OFF 10%
ON 90%
HIGH AVERAGE FIELD CURRENT
TIME
ON 10%
OFF 90%
LOW AVERAGE FIELD CURRENT TIME
FIGURE 54–22 The amount of time current is flowing through the field (rotor) determines the alternator output.
COMMAND DUTY CYCLE
ALTERNATOR OUTPUT VOLTAGE
10%
11.0 V
20%
11.6 V
30%
12.1 V
40%
12.7 V
50%
13.3 V
60%
13.8 V
70%
14.4 V
80%
14.9 V
90%
15.5 V
CHART 54–1 The output voltage is controlled by varying the duty cycle as controlled by the PCM.
4. Start-up mode. This mode is selected after engine start and commands a charging voltage of 14.5 volts for 30 seconds. After 30 seconds, the mode is changed depending on conditions. 5. Battery sulfation mode. This mode is commanded if the output voltage is less than 13.2 volts for 45 minutes, which can indicate that sulfated plates could be the cause. The target voltage is 13.9 to 15.5 volts for three minutes. After three minutes, the system returns to another mode based on conditions. 6. Headlight mode. This mode is selected when the headlights are on and the target voltage is 14.5 volts.
COMPUTER-CONTROLLED CHARGING SYSTEMS
Computer control of the charging system has the following advantages. 1. The computer controls the field of the alternator, which can pulse it on or off as needed for maximum efficiency, thereby saving fuel. NOTE: Some vehicle manufacturers, such as Honda/ Acura, use an electronic load control (ELC), which turns on the alternator when decelerating, where the additional
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CHAPTER 5 4
TECH TIP The Voltage Display Can Be a Customer Concern A customer may complain that the voltmeter reading on the dash fluctuates up and down. This may be normal as the computer-controlled charging system commands various modes of operation based on the operating conditions. Follow the vehicle manufacturer’s recommended procedures to verify proper operation.
load on the engine is simply used to help slow the vehicle. This allows the battery to be charged without placing a load on the engine, helping to increase fuel economy. 2. Engine idle can also be improved by turning on the alternator slowly, rather than all at once, if an electrical load is switched on, such as the air-conditioning system. 3. Most computers can also reduce the load on the electrical system if the demand exceeds the capacity of the charging system by reducing fan speed, shutting off rear window defoggers, or increasing engine speed to cause the alternator to increase the amperage output. NOTE: A commanded higher-than-normal idle speed may be the result of the computer compensating for an abnormal electrical load. This higher idle speed could indicate a defective battery or other electrical system faults. 4. The computer can monitor the charging system and set diagnostic trouble codes (DTCs) if a fault is detected. Many systems allow the service technician to control the charging of the alternator using a scan tool. 5. Because the charging system is computer controlled, it can be checked using a scan tool. Some vehicle systems allow the scan tool to activate the alternator field and then monitor the output to help detect fault locations. Always follow the vehicle manufacturer’s diagnostic procedure.
REVIEW QUESTIONS 1. How can a small electronic voltage regulator control the output of a typical 100 ampere alternator?
4. Why do voltage regulators include temperature compensation?
2. What are the component parts of a typical alternator?
5. How is AC voltage inside the alternator changed to DC voltage at the output terminal?
3. How is the computer used to control an alternator?
6. What is the purpose of an OAP or OAD?
CHAPTER QUIZ 1. Technician A says that the diodes regulate the alternator output voltage. Technician B says that the field current can be computer controlled. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 2. A magnetic field is created in the ______________ in an alternator (AC alternator). a. Stator c. Rotor b. Diodes d. Drive-end frame 3. The voltage regulator controls current through the _________. a. Alternator brushes c. Alternator field b. Rotor d. All of the above 4. Technician A says that two diodes are required for each stator winding lead. Technician B says that diodes change alternating current into direct current. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 5. The alternator output current is produced in the ______________. a. Stator c. Brushes b. Rotor d. Diodes (rectifier bridge) 6. Alternator brushes are constructed from ______________. a. Copper c. Carbon b. Aluminum d. Silver-copper alloy
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55
7. How much current flows through the alternator brushes? a. All of the alternator output flows through the brushes b. 25 to 35 A, depending on the vehicle c. 10 to 15 A d. 2 to 5 A 8. Technician A says that an alternator overrunning pulley is used to reduce vibration and noise. Technician B says that an overrunning alternator pulley or dampener uses a one-way clutch. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 9. Operating an alternator in a vehicle with a defective battery can harm the ______________. a. Diodes (rectifier bridge) b. Stator c. Voltage regulator d. Brushes 10. Technician A says that a wye-wound stator produces more maximum output than the same alternator equipped with a delta-wound stator. Technician B says that an alternator equipped with a delta-wound stator produces more maximum output than a wye-wound stator. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
CHARGING SYSTEM DIAGNOSIS AND SERVICE
OBJECTIVES: After studying Chapter 55, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “D” (Charging System Diagnosis and Repair). • Describe how to perform a charging voltage test. • Discuss how to perform an AC ripple voltage test. • Explain how to perform an alternator output test. • Explain how to disassemble an alternator and test its component parts. • Discuss how to check the wiring from the alternator to the battery. • Describe how to test the operation of a computer-controlled charging system. KEY TERMS: AC ripple voltage 590 • Alternator output test 592 • Charging voltage test 588 • Cores 597
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FIGURE 55–1 The digital multimeter should be set to read DC volts, with the red lead connected to the positive (⫹) battery terminal and the black meter lead connected to the negative (⫺) battery terminal.
CHARGING SYSTEM TESTING AND SERVICE BATTERY STATE OF CHARGE The charging system can be tested as part of a routine vehicle inspection or to determine the reason for a no-charge or reduced charging circuit performance. The battery must be at least 75% charged before testing the alternator and the charging system. A weak or defective battery will cause inaccurate test results. If in doubt, replace the battery with a known good shop battery for testing. CHARGING VOLTAGE TEST
The charging voltage test is the easiest way to check the charging system voltage at the battery. Use a digital multimeter to check the voltage, as follows: STEP 1
Select DC volts.
STEP 2
Connect the red meter lead to the positive (⫹) terminal of the battery and the black meter lead to the negative (⫺) terminal of the battery. NOTE: The polarity of the meter leads is not too important when using a digital multimeter. If the meter leads are connected backward on the battery, the resulting readout will simply have a negative (⫺) sign in front of the voltage reading.
STEP 3
Start the engine and increase the engine speed to about 2000 RPM (fast idle) and record the charging voltage. SEE FIGURE 55–1.
Specifications for charging voltage ⫽ 13.5 to 15 V
If the voltage is too high, check that the alternator is properly grounded.
If the voltage is lower than specifications, then there is a fault with the wiring or the alternator.
If the wiring and the connections are okay, then additional testing is required to help pinpoint the root cause. Replacement of the alternator and/or battery is often required if the charging voltage is not within factory specifications.
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FIGURE 55–2 A scan tool can be used to diagnose charging system problems.
?
FREQUENTLY ASKED QUESTION
What Is a Full-Fielding Test? Full fielding is a procedure used on older noncomputerized vehicles for bypassing the voltage regulator that could be used to determine if the alternator is capable of producing its designed output. This test is no longer performed for the following reasons. • The voltage regulator is built into the alternator, therefore requiring that the entire assembly be replaced even if just the regulator is defective. • When the regulator is bypassed, the alternator can produce a high voltage (over 100 volts in some cases) which could damage all of the electronic circuits in the vehicle. Always follow the vehicle manufacturer’s recommended testing procedures.
SCAN TESTING THE CHARGING CIRCUIT
Most vehicles that use a computer-controlled charging system can be diagnosed using a scan tool. Not only can the charging voltage be monitored, but also in many vehicles, the field circuit can be controlled and the output voltage monitored to check that the system is operating correctly. SEE FIGURE 55–2. NOTE: Some charging systems, such as those on many Honda/Acura vehicles, use an electronic load detection circuit that energizes the field circuit only when an electrical load is detected. For example, if the engine is running and there are no accessories on, the voltage read at the battery may be 12.6 V, which could indicate that the charging system is not operating. In this situation, turning on the headlights or an accessory should cause the computer to activate the field circuit, and the alternator should produce normal charging voltage.
OUTPUT TERMINAL
VOLTAGE SENSING TERMINAL
TEST LIGHT
FIGURE 55–3 Before replacing an alternator, the wise technician checks that battery voltage is present at the output and battery voltage sense terminals. If not, then there is a fault in the wiring.
TECH TIP Use a Test Light to Check for a Defective Fusible Link Most alternators use a fusible link or mega fuse between the output terminal and the positive (⫹) terminal of the battery. If this fusible link or fuse is defective (blown), then the charging system will not operate at all. Many alternators have been replaced repeatedly because of a blown fusible link that was not discovered until later. A quick and easy test to check if the fusible link is okay is to touch a test light to the output terminal. With the other end of the test light attached to a good ground, the fusible link or mega fuse is okay if the light lights. This test confirms that the circuit between the alternator and the battery has continuity. SEE FIGURE 55–3.
DRIVE BELT INSPECTION AND ADJUSTMENT BELT VISUAL INSPECTION
It is generally recommended that all belts be inspected regularly and replaced as needed. Replace any serpentine belt that has more than three cracks in any one rib that appears in a 3 in. span. Check service information for the specified procedure and recommended replacement interval. SEE FIGURE 55–4.
BELT TENSION MEASUREMENT
If the vehicle does not use a belt tensioner, then a belt tension gauge is needed to achieve the specified belt tension. Install the belt and operate the engine with all of the accessories turned on to “run-in” the belt for at least five minutes. Adjust the tension of the accessory drive belt to factory specifications or use the following table for an example of the proper tension based on the size of the belt. There are four ways that vehicle manufacturers specify that the belt tension is within factory specifications. 1. Belt tension gauge. A belt tension gauge is needed to determine if it is at the specified belt tension. Install the belt and operate the engine with all of the accessories turned on to “run-in” the belt for at least five minutes. Adjust the tension
FIGURE 55–4 This accessory drive belt is worn and requires replacement. Newer belts are made from ethylene propylene diene monomer (EPDM). This rubber does not crack like older belts and may not show wear even though the ribs do wear and can cause slippage.
TECH TIP The Hand Cleaner Trick Lower-than-normal alternator output could be the result of a loose or slipping drive belt. All belts (V and serpentine multigroove) use an interference angle between the angle of the Vs of the belt and the angle of the Vs on the pulley. As the belt wears, the interference angles are worn off of both edges of the belt. As a result, the belt may start to slip and make a squealing sound even if tensioned properly. A common trick used to determine if the noise is belt related is to use grit-type hand cleaner or scouring powder. With the engine off, sprinkle some powder onto the pulley side of the belt. Start the engine. The excess powder will fly into the air, so get away from under the hood when the engine starts. If the belts are now quieter, you know that it was the glazed belt that made the noise. The noise can sound exactly like a noisy bearing. Therefore, before you start removing and replacing parts, try the hand cleaner trick. Often, the grit from the hand cleaner will remove the glaze from the belt and the noise will not return. However, if the belt is worn or loose, the noise will return and the belt should be replaced. A fast, alternative method to see if the noise is from the belt is to spray water from a squirt bottle at the belt with the engine running. If the noise stops, the belt is the cause of the noise. The water quickly evaporates and, therefore, unlike the gritty hand cleaner, water simply finds the problem—it does not provide a short-term fix.
of the accessory drive belt to factory specifications, or see CHART 55–1 for an example of the proper tension based on the size of the belt. 2. Marks on a tensioner. Many tensioners have marks that indicate the normal operating tension range for the accessory drive belt. Check service information for the preferred location of the tensioner mark. SEE FIGURE 55–5.
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SERPENTINE BELTS NUMBER OF RIBS USED
TENSION RANGE (LB)
3
45–60
4
60–80
5
75–100
6
90–125
7
105–145 V-BELTS
V-BELT TOP WIDTH (IN.)
TENSION RANGE (LB)
1/4
45–65
5/16
60–85
25/64
85–115
31/64
105–145
CHART 55–1 Typical belt tension for various widths of belts. Tension is the force needed to depress the belt as displayed on a belt tension gauge.
FIGURE 55–6 This overrunning alternator dampener (OAD) is longer than an overrunning alternator pulley (OAP) because it contains a dampener spring as well as a one way clutch. Be sure to check that it locks in one direction.
TECH TIP Check the Overrunning Clutch If low or no alternator output is found, remove the alternator drive belt and check the overrunning alternator pulley (OAP) or overrunning alternator dampener (OAD) for proper operation. Both types of overrunning clutches use a one-way clutch. Therefore, the pulley should freewheel in one direction and rotate the alternator rotor when rotated in the opposite direction. SEE FIGURE 55–6.
TESTING AC RIPPLE VOLTAGE The procedure to check for AC ripple voltage includes the following steps.
FIGURE 55–5 Check service information for the exact marks where the tensioner should be located for proper belt tension.
3. Torque wrench reading. Some vehicle manufacturers specify that a beam-type torque wrench be used to determine the torque needed to rotate the tensioner. If the torque reading is below specifications, the tensioner must be replaced. 4. Deflection. Depress the belt between the two pulleys that are the farthest apart; the flex or deflection should be 1/2 in. (13 mm).
STEP 1
Set the digital meter to read AC volts.
STEP 2
Start the engine and operate it at 2000 RPM (fast idle).
STEP 3
Connect the voltmeter leads to the positive and negative battery terminals.
STEP 4
Turn on the headlights to provide an electrical load on the alternator.
NOTE: A more accurate reading can be obtained by touching the meter lead to the output or “battery” terminal of the alternator. SEE FIGURE 55–7. The results should be interpreted as follows: If the rectifier diodes are good, the voltmeter should read less than 400 mV (0.4 volt) AC. If the reading is over 500 mV (0.5 volt) AC, the rectifier diodes are defective. NOTE: Many conductance testers, such as Midtronic and Snap-On, automatically test for AC ripple.
TESTING AC RIPPLE CURRENT
AC RIPPLE VOLTAGE CHECK PRINCIPLES
A good alternator should produce very little AC voltage or current output. It is the purpose of the diodes in the alternator to rectify or convert most AC voltage into DC voltage. While it is normal to measure some AC voltage from an alternator, excessive AC voltage, called AC ripple, is undesirable and indicates a fault with the rectifier diodes or stator windings inside the alternator.
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All alternators should create direct current (DC) if the diodes and stator windings are functioning correctly. A mini clamp-on meter capable of measuring AC amperes can be used to check the alternator. A good alternator should produce less than 10% of its rated amperage output in AC ripple amperes. For example, an alternator rated at 100 amperes should not produce more than 10 amperes AC ripple (100 ⫻ 10% ⫽ 10). It is normal for a good alternator to produce 3 or 4 A of AC ripple current to the battery. Only if the AC ripple current exceeds 10% of the rating of the alternator should the alternator be repaired or replaced.
DIGITAL MULTIMETER AC
MEASURING THE AC RIPPLE FROM THE ALTERNATOR TELLS A LOT ABOUT ITS CONDITION. IF THE AC RIPPLE IS ABOVE 500 MILLIVOLTS, OR 0.5 VOLTS, LOOK FOR A PROBLEM IN THE DIODES OR STATOR. IF THE RIPPLE IS BELOW 500 MILLIVOLTS, CHECK THE ALTERNATOR OUTPUT TO DETERMINE ITS CONDITION.
0.078 V
0 1 2 3 4 5 6 7 8
9 0
mV mA A
V
A
V
A
mA A
COM
V
FIGURE 55–9 A mini clamp-on meter can be used to measure alternator output as shown here (105.2 Amp). Then the meter can be used to check AC current ripple by selecting AC Amps on the rotary dial. AC ripple current should be less than 10% of the DC current output. FIGURE 55–7 Testing AC ripple at the output terminal of the alternator is more accurate than testing at the battery due to the resistance of the wiring between the alternator and the battery. The reading shown on the meter, set to AC volts, is only 78 mV (0.078 V), far below what the reading would be if a diode were defective.
TEST PROCEDURE
To measure the AC current to the battery, perform the following steps. STEP 1
Start the engine and turn on the lights to create an electrical load on the alternator.
STEP 2
Using a mini clamp-on digital multimeter, place the clamp around either all of the positive (⫹) battery cables or all of the negative (⫺) battery cables. An AC/DC current clamp adapter can also be used with a conventional digital multimeter set on the DC millivolts scale.
STEP 3
To check for AC current ripple, switch the meter to read AC amperes and record the reading. Read the meter display.
STEP 4
The results should be within 10% of the specified alternator rating. A reading of greater than 10 amperes AC indicates defective alternator diodes. SEE FIGURE 55–9.
CHARGING SYSTEM VOLTAGE DROP TESTING FIGURE 55–8 Charging system voltage can be easily checked at the lighter plug by connecting a lighter plug to the voltmeter through a double banana plug.
TECH TIP The Lighter Plug Trick Battery voltage measurements can be read through the lighter socket. Simply construct a test tool using a lighter plug at one end of a length of two-conductor wire and the other end connected to a double banana plug. The double banana plug will fit most meters in the common (COM) terminal and the volt terminal of the meter. This is handy to use while road testing the vehicle under real-life conditions. Both DC voltage and AC ripple voltage can be measured. SEE FIGURE 55–8.
ALTERNATOR WIRING
For the proper operation of any charging system, there must be good electrical connections between the battery positive terminal and the alternator output terminal. The alternator must also be properly grounded to the engine block. Many manufacturers of vehicles run the lead from the output terminal of the alternator to other connectors or junction blocks that are electrically connected to the positive terminal of the battery. If there is high resistance (a high voltage drop) in these connections or in the wiring itself, the battery will not be properly charged.
VOLTAGE DROP TEST PROCEDURE
When there is a suspected charging system problem (with or without a charge indicator light on), simply follow these steps to measure the voltage drop of the insulated (power-side) charging circuit. STEP 1
Start the engine and run it at a fast idle (about 2000 engine RPM).
STEP 2
Turn on the headlights to ensure an electrical load on the charging system.
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BATTERY (OUTPUT)
ENGINE AT 2,000 RPM. CHARGING SYSTEM LOADED TO 20A
DIGITAL MULTIMETER RECORD
MAX MIN
HZ
MIN MAX
HZ
mV mA
TYPICAL MAXIMUM READING 0.4V
DIGITAL MULTIMETER RECORD
MAX MIN
HZ
mA A
COM MIN MAX
HZ
mV mA
TYPICAL MAXIMUM READING 0.2V
mA A
COM
VOLTAGE DROP - INSULATED CHARGING CIRCUIT
VOLTAGE DROP - CHARGING GROUND CIRCUIT
FIGURE 55–10 Voltmeter hookup to test the voltage drop of the charging circuit. STEP 3
Using any voltmeter set to read DC volts, connect the positive test lead (red) to the output terminal of the alternator. Attach the negative test lead (black) to the positive post of the battery.
The results should be interpreted as follows: 1. If there is less than a 0.4 volt (400 mV) reading, then all wiring and connections are satisfactory. 2. If the voltmeter reads higher than 0.4 volt, there is excessive resistance (voltage drop) between the alternator output terminal and the positive terminal of the battery. 3. If the voltmeter reads battery voltage (or close to battery voltage), there is an open circuit between the battery and the alternator output terminal. To determine whether the alternator is correctly grounded, maintain the engine speed at 2000 RPM with the headlights on. Connect the positive voltmeter lead to the case of the alternator and the negative voltmeter lead to the negative terminal of the battery. The voltmeter should read less than 0.2 volt (200 mV) if the alternator is properly grounded. If the reading is over 0.2 volt, connect one end of an auxiliary ground wire to the case of the alternator and the other end to a good engine ground. SEE FIGURE 55–10.
FIGURE 55–11 A typical tester used to test batteries as well as the cranking and charging system. Always follow the operating instructions.
CARBON PILE TEST PROCEDURE
A carbon pile tester uses plates of carbon to create an electrical load. A carbon pile test is used to load test a battery and/or an alternator. SEE FIGURE 55–11. The testing procedure for alternator output is as follows: STEP 1
Connect the starting and charging test leads according to the manufacturer’s instructions, which usually include installing the amp clamp around the output wire near the alternator.
STEP 2
Turn off all electrical accessories to be sure that the tester is measuring the true output of the alternator.
STEP 3
Start the engine and operate it at 2000 RPM (fast idle). Turn the load increase control slowly to obtain the highest reading on the ammeter scale. Do not allow the voltage to drop below 12.6 volts. Note the ampere reading.
STEP 4
Add 5 to 7 amperes to the reading because this amount of current is used by the ignition system to operate the engine.
ALTERNATOR OUTPUT TEST PRELIMINARY CHECKS
An alternator output test measures the current (amperes) of the alternator. A charging circuit may be able to produce correct charging circuit voltage, but not be able to produce adequate amperage output. If in doubt about charging system output, first check the condition of the alternator drive belt. With the engine off, attempt to rotate the fan of the alternator by hand. Replace or tighten the drive belt if the alternator fan can be rotated this way.
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TECH TIP Use a Fused Jumper Wire as a Diagnostic Tool
FIGURE 55–12 The best place to install a charging system tester amp probe is around the alternator output terminal wire, as shown. STEP 5
When diagnosing an alternator charging problem, try using a fused jumper wire to connect the positive and negative terminals of the alternator directly to the positive and negative terminals of the battery. If a definite improvement is noticed, the problem is in the wiring of the vehicle. High resistance, due to corroded connections or loose grounds, can cause low alternator output, repeated regulator failures, slow cranking, and discharged batteries. A voltage drop test of the charging system can also be used to locate excessive resistance (high voltage drop) in the charging circuit, but using a fused jumper wire is often faster and easier.
Compare the output reading to factory specifications. The rated output may be stamped on the alternator or can be found in service information.
CAUTION: NEVER disconnect a battery cable with the engine running. All vehicle manufacturers warn not to do this, because this was an old test, before alternators, to see if a generator could supply current to operate the ignition system without a battery. When a battery cable is removed, the alternator (or PCM) will lose the battery voltage sense signal. Without a battery voltage sense circuit, the alternator will do one of two things, depending on the make and model of vehicle.
The alternator output can exceed 100 volts. This high voltage may not only damage the alternator but also electrical components in the vehicle, including the PCM and all electronic devices.
The alternator stops charging as a fail safe measure to protect the alternator and all of the electronics in the vehicle from being damaged due to excessively high voltage.
TECH TIP Bigger Is Not Always Better Many technicians are asked to install a higher output alternator to allow the use of emergency equipment or other high-amperage equipment such as a high-wattage sound system. Although many higher output units can be physically installed, it is important not to forget to upgrade the wiring and the fusible link(s) in the alternator circuit. Failure to upgrade the wiring could lead to overheating. The usual failure locations are at junctions or electrical connectors.
3. Turn the blower motor to high speed. 4. Turn the headlights on bright. 5. Turn on the rear defogger. 6. Turn on the windshield wipers.
MINIMUM REQUIRED ALTERNATOR OUTPUT PURPOSE All charging systems must be able to supply the electrical demands of the electrical system. If lights and accessories are used constantly and the alternator cannot supply the necessary ampere output, the battery will be drained. To determine the minimum electrical load requirements, connect an inductive ammeter probe around either battery cable or the alternator output cable. SEE FIGURE 55–12.
7. Turn on any other accessories that may be used continuously (do not operate the horn, power door locks, or other units that are not used for more than a few seconds). 8. Observe the ammeter. The current indicated is the electrical load that the alternator is able to exceed to keep the battery fully charged.
TEST RESULTS The minimum acceptable alternator output is 5 amperes greater than the accessory load. A negative (discharge) reading indicates that the alternator is not capable of supplying the current (amperes) that may be needed.
NOTE: If using an inductive pickup ammeter, be certain that the pickup is over all the wires leaving the battery terminal. Failure to include the small body ground wire from the negative battery terminal to the body or the small positive wire (if testing from the positive side) will greatly decrease the current flow readings.
PROCEDURE After connecting an ammeter correctly in the battery circuit, continue as follows: 1. Start the engine and operate to about 2000 RPM (fast idle). 2. Turn the heat selector to air conditioning (if the vehicle is so equipped).
ALTERNATOR REMOVAL After diagnosis of the charging system has determined that there is a fault with the alternator, it must be removed safely from the vehicle. Always check service information for the exact procedure to follow on the vehicle being serviced. A typical removal procedure includes the following steps. STEP 1
Before disconnecting the negative battery cable, use a test light or a voltmeter and check for battery voltage at the output terminal of the alternator. A complete circuit must
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FIGURE 55–13 Replacing an alternator is not always as easy as it is from a Buick with a 3800 V-6, where the alternator is easy to access. Many alternators are difficult to access, and require the removal of other components.
FIGURE 55–14 Always mark the case of the alternator before disassembly to be assured of correct reassembly. 12 O’CLOCK THREADED ADJUSTING LUG
TECH TIP
1
The Sniff Test
2
CONNECTOR POSITIONS
9 O’CLOCK
3 O’CLOCK
BAT
R
1
2
STEP 2
1
exist between the alternator and the battery. If there is no voltage at the alternator output terminal, check for a blown fusible link or other electrical circuit fault.
R
When checking for the root cause of an alternator failure, one test that a technician could do is to sniff (smell) the alternator. If the alternator smells like a dead rat (rancid smell), the stator windings have been overheated by trying to charge a discharged or defective battery. If the battery voltage is continuously low, the voltage regulator will continue supplying full-field current to the alternator. The voltage regulator is designed to cycle on and off to maintain a narrow charging system voltage range. If the battery voltage is continually below the cutoff point of the voltage regulator, the alternator is continually producing current in the stator windings. This constant charging can often overheat the stator and burn the insulating varnish covering the stator windings. If the alternator fails the sniff test, the technician should replace the stator and other alternator components that are found to be defective and replace or recharge and test the battery.
2
R
SPOOL MOUNTING LUG 6 O’CLOCK
FIGURE 55–15 Explanation of clock positions. Because the four through bolts are equally spaced, it is possible for an alternator to be installed in one of four different clock positions. The connector position is determined by viewing the alternator from the diode end with the threaded adjusting lug in the up or 12 o’clock position. Select the 3 o’clock, 6 o’clock, 9 o’clock, or 12 o’clock position to match the unit being replaced.
Disconnect the negative (⫺) terminal from the battery. (Use a memory saver to maintain radio, memory seats, and other functions.)
?
STEP 3
Remove the accessory drive belt that drives the alternator.
What Is a “Clock Position”?
STEP 4
Remove electrical wiring, fasteners, spacers, and brackets, as necessary, and remove the alternator from the vehicle. SEE FIGURE 55–13.
Most alternators of a particular manufacturer can be used on a variety of vehicles, which may require wiring connections placed in various locations. For example, a Chevrolet and a Buick alternator may be identical except for the position of the rear section containing the electrical connections. The four through bolts that hold the two halves together are equally spaced; therefore, the rear alternator housing can be installed in any one of four positions to match the wiring needs of various models. Always check the clock position of the original and be sure that it matches the replacement unit. SEE FIGURE 55–15.
ALTERNATOR DISASSEMBLY DISASSEMBLY PROCEDURE STEP 1
Mark the case with a scratch or with chalk to ensure proper reassembly of the alternator case. SEE FIGURE 55–14.
STEP 2
After the through bolts have been removed, carefully separate the two halves. The stator windings must stay with the
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FREQUENTLY ASKED QUESTION
TESTING STATOR
TESTING AN ALTERNATOR ROTOR USING AN OHMMETER
(CHECK FOR OPENS) OHMMETER
CHECKING FOR GROUNDS (SHOULD READ INFINITY IF ROTOR IS NOT GROUNDED)
1.11
OHMMETER OL
NOTE: OHMMETER SHOULD READ LOW OHMS
1.11
STATOR IS OPEN IF METER READS INFINITY (OL)
3.1
OL
IF OHMMETER READS ANY RESISTANCE EXCEPT INFINITY (OL), STATOR IS GROUNDED
FIGURE 55–17 If the ohmmeter reads infinity between any two of the three stator windings, the stator is open and, therefore, defective. The ohmmeter should read infinity between any stator lead and the steel laminations. If the reading is less than infinity, the stator is grounded. Stator windings cannot be tested if shorted because the normal resistance is very low.
OHMMETER
FIGURE 55–16 Testing an alternator rotor using an ohmmeter.
STATOR TESTING rear case. When this happens, the brushes and springs will fall out. STEP 3
Remove the rectifier assembly and voltage regulator.
The stator must be disconnected from the diodes (rectifiers) before testing. Because all three windings of the stator are electrically connected (either wye or delta), an ohmmeter can be used to check a stator.
ROTOR TESTING
The slip rings on the rotor should be smooth and round (within 0.002 in. of being perfectly round).
If grooved, the slip rings can be machined to provide a suitable surface for the brushes. Do not machine beyond the minimum slip-ring dimension as specified by the manufacturer.
If the slip rings are discolored or dirty, they can be cleaned with 400-grit or fine emery (polishing) cloth. The rotor must be turned while being cleaned to prevent flat spots on the slip rings.
Measure the resistance between the slip rings using an ohmmeter. Typical resistance values and results include the following: 1. The resistance measured between either slip ring and the steel rotor shaft should be infinity (OL). If there is continuity, then the rotor is shorted to ground. 2. Rotor resistance range is normally between 2.4 and 6 ohms. 3. If the resistance is below specification, the rotor is shorted.
4. If the resistance is above specification, the rotor connections are corroded or open. If the rotor is found to be bad, it must be replaced or repaired at a specialized shop. SEE FIGURE 55–16. NOTE: The cost of a replacement rotor may exceed the cost of an entire rebuilt alternator. Be certain, however, that the rebuilt alternator is rated at the same output as the original or higher.
There should be low resistance at all three stator leads (continuity). There should not be continuity (in other words, there should be a meter reading of infinity ohms) when the stator is tested between any stator lead and the metal stator core. If there is continuity, the stator is shorted-to-ground and must be repaired or replaced. SEE FIGURE 55–17.
NOTE: Because the resistance is very low for a normal stator, it is generally not possible to test for a shorted (copperto-copper) stator. A shorted stator will, however, greatly reduce alternator output. An ohmmeter cannot detect an open stator if the stator is delta wound. The ohmmeter will still indicate low resistance because all three windings are electrically connected.
TESTING THE DIODE TRIO Many alternators are equipped with a diode trio. A diode is an electrical one-way check valve that permits current to flow in only one direction. Because trio means “three,” a diode trio is three diodes connected together. SEE FIGURE 55–18. The diode trio is connected to all three stator windings. The current generated in the stator flows through the diode trio to the internal voltage regulator. The diode trio is designed to supply current for the field (rotor) and turns off the charge indicator light when the alternator voltage equals or exceeds the battery voltage. If one of the three diodes in the diode trio is defective (usually open), the alternator may produce close-to-normal output; however, the charge indicator light will be on dimly.
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BRUSH RETAINER PIN HOLE
FIGURE 55–18 Typical diode trio. If one leg of a diode trio is open, the alternator may produce close to normal output, but the charge indicator light on the dash will be on dimly.
FIGURE 55–20 A brush holder assembly with new brushes installed. The holes in the brushes are used to hold the brushes up in the holder when it is installed in the alternator. After the rotor has been installed, the retaining pin is removed which allows the brushes to contact the slip rings of the rotor.
Reverse the test leads. A good diode should have high resistance (OL) one way (reverse bias) and low voltage drop of 0.5 to 0.7 V (500 to 700 mV) the other way (forward bias).
RESULTS Open or shorted diodes must be replaced. Most alternators group or combine all positive and all negative diodes in the one replaceable rectifier component.
FIGURE 55–19 A typical rectifier bridge that contains all six diodes in one replaceable assembly. A diode trio should be tested with a digital multimeter. The meter should be set to the diode-check position. The multimeter should indicate 0.5 to 0.7 V (500 to 700 mV) one way and OL (overlimit) after reversing the test leads and touching all three connectors of the diode trio.
TESTING THE RECTIFIER TERMINOLOGY The rectifier assembly usually is equipped with six diodes including three positive diodes and three negative diodes (one positive and one negative for each winding of the stator). METER SETUP
The rectifier(s) (diodes) should be tested using a multimeter that is set to “diode check” position on the digital multimeter (DMM). Because a diode (rectifier) should allow current to flow in only one direction, each diode should be tested to determine if the diode allows current flow in one direction and blocks current flow in the opposite direction. To test some alternator diodes, it may be necessary to unsolder the stator connections. SEE FIGURE 55–19. Accurate testing is not possible unless the diodes are separated electrically from other alternator components.
TESTING PROCEDURE
Connect the leads to the leads of the diode (pigtail and housing of the rectifier bridge). Read the meter.
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REASSEMBLING THE ALTERNATOR BRUSH HOLDER REPLACEMENT Alternator carbon brushes often last for many years and require no scheduled maintenance. The life of the alternator brushes is extended because they conduct only the field (rotor) current, which is normally only 2 to 5 amperes. The alternator brushes should be inspected when the alternator is disassembled and should be replaced when worn to less than 1/2 in. long. Brushes are commonly purchased assembled together in a brush holder. After the brushes are installed (usually retained by two or three screws) and the rotor is installed in the alternator housing, a brush retainer pin can be pulled out through an access hole in the rear of the alternator, allowing the brushes to be pressed against the slip rings by the brush springs. SEE FIGURE 55–20. BEARING SERVICE AND REPLACEMENT
The bearings of an alternator must be able to support the rotor and reduce friction. An alternator must be able to rotate at up to 15,000 RPM and withstand the forces created by the drive belt. The front bearing is usually a ball bearing type and the rear can be either a smaller roller or ball bearing. The old or defective bearing can sometimes be pushed out of the front housing and the replacement pushed in by applying pressure with a socket or pipe against the outer edge of the bearing (outer race). Replacement bearings are usually prelubricated and seated. Many alternator front bearings must be removed from the rotor using a special puller.
REAL WORLD FIX The Two-Minute Alternator Repair A Chevrolet pickup truck was brought to a shop for routine service. The customer stated that the battery required a jump start after a weekend of sitting. The technician tested the battery and charging system voltage using a small handheld digital multimeter. The battery voltage was 12.4 volts (about 75% charged), but the charging voltage was also 12.4 volts at 2000 RPM. Because normal charging voltage should be 13.5 to 15 volts, it was obvious that the charging system was not operating correctly. The technician checked the dash and found that the “charge” light was not on. Before removing the alternator for service, the technician checked the wiring connection on the alternator. When the connector was removed, it was discovered to be rusty. After the contacts were cleaned, the charging system was restored to normal operation. The technician had learned that the simple things should always be checked first before tearing into a big (or expensive) repair.
ALTERNATOR ASSEMBLY After testing or servicing, the alternator rectifier(s), regulator, stator, and brush holder must be reassembled using the following steps. STEP 1
STEP 2
STEP 3
If the brushes are internally mounted, insert a wire through the holes in the brush holder to hold the brushes against the springs. Install the rotor and front-end frame in proper alignment with the mark made on the outside of the alternator housing. Install the through bolts. Before removing the wire pin holding the brushes, spin the alternator pulley. If the alternator is noisy or not rotating freely, the alternator can easily be disassembled again to check for the cause. After making certain the alternator is free to rotate, remove the brush holder pin and spin the alternator again by hand. The noise level may be slightly higher with the brushes released onto the slip rings. Alternators should be tested on a bench tester, if available, before they are reinstalled on a vehicle. When installing the alternator on the vehicle, be certain that all mounting bolts and nuts are tight. The battery terminal should be covered with a plastic or rubber protective cap to help prevent accidental shorting to ground, which could seriously damage the alternator.
REMANUFACTURED ALTERNATORS Remanufactured or rebuilt alternators are totally disassembled and rebuilt. Even though there are many smaller rebuilders who may not replace all worn parts, the major national remanufacturers totally remanufacture the alternator. Old alternators (called cores) are totally disassembled and cleaned. Both bearings are replaced and all components are tested. Rotors are rewound to original specifications if required. The rotor windings are not counted but are rewound on the rotor “spool,” using the correct-gauge copper wire, to the weight specified by the original manufacturer. New slip rings are replaced as required, soldered to the rotor spool windings, and machined. The rotors are also balanced and measured to ensure that the outside diameter of the rotor meets specifications. An undersized rotor will produce less alternator output because the field must be close to the stator windings for maximum output. Bridge rectifiers are replaced, if required. Every alternator is then assembled and tested for proper output, boxed, and shipped to a warehouse. Individual parts stores (called jobbers) purchase parts from various regional or local warehouses.
ALTERNATOR INSTALLATION Before installing a replacement alternator, check service information for the exact procedure to follow for the vehicle being serviced. A typical installation procedure includes the following steps. STEP 1
Verify that the replacement alternator is the correct unit for the vehicle.
STEP 2
Install the alternator wiring on the alternator and install the alternator.
STEP 3
Check the condition of the drive belt and replace, if necessary. Install the drive belt over the drive pulley.
STEP 4
Properly tension the drive belt.
STEP 5
Tighten all fasteners to factory specifications.
STEP 6
Double-check that all fasteners are correctly tightened and remove all tools from the engine compartment area.
STEP 7
Reconnect the negative battery cable.
STEP 8
Start the engine and verify proper charging circuit operation.
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ALTERNATOR OVERHAUL
1
Before the alternator is disassembled, it is spin tested and connected to a scope to check for possible defective components.
2
3
The first step is to remove the drive pulley. This rebuilder is using an electric impact wrench to accomplish the task.
4
5
Remove the external fan (if equipped) and then the spacers as shown.
6
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The scope pattern shows that the voltage output is far from being a normal pattern. This pattern indicates serious faults in the rectifier diodes.
Carefully inspect the drive galley for damage of embedded rubber from the drive belt. The slightest fault can cause a vibration, noise, or possible damage to the alternator.
Next pop off the plastic cover (shield) covering the stator/rectifier connection.
STEP BY STEP
7
After the cover has been removed, the stator connections to the rectifier can be seen.
8
9
Before separating the halves of the case, this technician uses a punch to mark both halves.
10
11
The drive-end housing and the stator are being separated from the rear (slip-ring-end) housing.
Using a diagonal cutter, cut the weld to separate the stator from the rectifier.
12
After the case has been marked, the through-bolts are removed.
The stator is checked by visual inspection for discoloration or other physical damage, and then checked with an ohmmeter to see if the windings are shorted-to-ground. CONTINUED
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ALTERNATOR OVERHAUL
(CONTINUED)
13
The front bearing is removed from the drive-end housing using a press.
14
A view of the slip-ring-end (SRE) housing showing the black plastic shield, which helps direct air flow across the rectifier.
15
A punch is used to dislodge the plastic shield retaining clips.
16
After the shield has been removed, the rectifier, regulator, and brush holder assembly can be removed by removing the retaining screws.
17
The hear transfer grease is visible when the rectifier assembly is lifted out of the rear housing.
18
The parts are placed into a tumbler where ceramic stones and a water-based solvent are used to clean the parts.
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STEP BY STEP
19
This rebuilder is painting the housing using a highquality industrial grade spray paint to make the rebuilt alternator look like new.
20
The slip rings on the rotor are being machined on a lathe.
21
The rotor is being tested using an ohmmeter. The specifications for the resistance between the slip rings on the CS-130 are 2.2 to 3.5 ohms.
22
The rotor is also tested between the slip ring and the rotor shaft. This reading should be infinity.
24
Silicone heat transfer compound is applied to the heat sink of the new rectifier.
23
A new rectifier. This replacement unit is significantly different than the original but is designed to replace the original unit and meets the original factory specifications.
CONTINUED
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(CONTINUED)
25
Replacement brushes and springs are assembled into the brush holder.
26
27
Here is what the CS alternator looks like after installing the new brush holder assembly, rectifier bridge, and voltage regulator.
28
The junction between the rectifier bridge and the voltage regulator is soldered.
30
Before the stator windings can be soldered to the rectifier bridge, the varnish insulation is removed from the ends of the leads.
29 602
The plastic deflector shield is snapped back into location using a blunt chisel and a hammer. This shield directs the airflow from the fan over the rectifier bridge and voltage regulator.
CHAPTER 5 5
The brushes are pushed into the brush holder and retained by a straight wire, which extends through the rear housing of the alternator. This wire is then pulled out when the unit is assembled.
STEP BY STEP
31
After the stator has been inserted into the rear housing the stator leads are soldered to the copper lugs of the rectifier bridge.
32
33
The slip-ring-end (SRE) housing is aligned with the marks made during disassembly and is pressed into the drive-end (DE) housing.
34
35
The external fan and drive pulley are installed and the retaining nut is tightened on the rotor shaft.
36
New bearings are installed. A spacer is placed between the bearing and the slip rings to help prevent the possibility that the bearing could move on the shaft and short against the slip ring.
The retaining bolts, which are threaded into the drive-end housing from the back of the alternator are installed.
The scope pattern shows that the diodes and stator are functioning correctly and voltage check indicates that the voltage regulator is also functioning correctly.
C H ARG I N G SYST E M D I AG N O SI S A N D S ERVIC E
603
REVIEW QUESTIONS 1. How does a technician test the voltage drop of the charging circuit? 2. How does a technician measure the amperage output of an alternator?
3. What tests can be performed to determine whether a diode or stator is defective before removing the alternator from the vehicle?
CHAPTER QUIZ 1. To check the charging voltage, connect a digital multimeter (DMM) to the positive (⫹) and the negative (⫺) terminals of the battery and select ______________. a. DC volts c. DC amps b. AC volts d. AC amps 2. To check for ripple voltage from the alternator, connect a digital multimeter (DMM) and select ______________. a. DC volts c. DC amps b. AC volts d. AC amps 3. The maximum allowable alternating current (AC) in amperes that is being sent to the battery from the alternator is ______________. a. 0.4 A b. 1 to 3 A c. 3 to 4 A d. 10% of the rated output of the alternator 4. Why should the lights be turned on when checking for ripple voltage or alternating current from the alternator? a. To warm the battery b. To check that the battery is fully charged c. To create an electrical load for the alternator d. To test the battery before conducting other tests 5. An acceptable charging circuit voltage on a 12 volt system is ______________. a. 13.5 to 15 volts c. 12 to 14 volts b. 12.6 to 15.6 volts d. 14.9 to 16.1 volts 6. Technician A says that the computer can be used to control the output of the alternator by controlling the field current. Technician B says that voltage regulators control the alternator output by controlling the field current through the rotor. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
chapter
56
7. Technician A says that a voltage drop test of the charging circuit should only be performed when current is flowing through the circuit. Technician B says to connect the leads of a voltmeter to the positive and negative terminals of the battery to measure the voltage drop of the charging system. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 8. When testing an alternator rotor, if an ohmmeter shows zero ohms with one meter lead attached to the slip rings and the other meter lead touching the rotor shaft, the rotor is ______________. a. Okay (normal) b. Defective (shorted-to-ground) c. Defective (shorted-to-voltage) d. Okay (rotor windings are open) 9. An alternator diode is being tested using a digital multimeter set to the diode-check position. A good diode will read ______________ if the leads are connected one way across the diode and ______________ if the leads are reversed. a. 300/300 c. OL/OL b. 0.475/0.475 d. 0.551/OL 10. An alternator could test as producing lower-than-normal output, yet be okay, if the ______________. a. Battery is weak or defective b. Engine speed is not high enough during testing c. Drive belt is loose or slipping d. All of the above
LIGHTING AND SIGNALING CIRCUITS
OBJECTIVES: After studying Chapter 56, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “E” (Lighting System Diagnosis and Repair). • Read and interpret a bulb chart. • Describe how interior and exterior lighting systems work. • Read and interpret a bulb chart. • Discuss troubleshooting procedures for lighting and signaling circuits. KEY TERMS: AFS 616 • Brake lights 608 • Candlepower 605 • CHMSL 609 • Color shift 614 • Composite headlight 613 • Courtesy lights 617 • DOT 610 • DRL 617 • Feedback 620 • Fiber optics 617 • Flasher relay 611 • Hazard warning 611 • HID 614 • Hybrid flasher 611 • Kelvin (K) 614 • LED 609 • Rheostat 612 • Trade number 605 • Troxler effect 619 • Xenon headlights 614
604
CHAPTER 5 6
INTRODUCTION The vehicle has many different lighting and signaling systems, each with its own specific components and operating characteristics. The major light-related circuits and systems covered include:
Exterior lighting
Headlights (halogen, HID, and LED)
Bulb trade numbers
Brake lights
Turn signals and flasher units
Courtesy lights
Light-dimming rearview mirrors
DOUBLE CONTACT 1157/2057 BULBS
SINGLE CONTACT 1156 BULBS
WEDGE 194 BULB
EXTERIOR LIGHTING HEADLIGHT SWITCH CONTROL Exterior lighting is controlled by the headlight switch, which is connected directly to the battery on most vehicles. Therefore, if the light switch is left on manually, the lights could drain the battery. Older headlight switches contained a built-in circuit breaker. If excessive current flows through the headlight circuit, the circuit breaker will momentarily open the circuit, then close it again. The result is headlights that flicker on and off rapidly. This feature allows the headlights to function, as a safety measure, in spite of current overload. The headlight switch controls the following lights on most vehicles, usually through a module. 1. Headlights 2. Taillights 3. Side-marker lights 4. Front parking lights 5. Dash lights 6. Interior (dome) light(s)
COMPUTER-CONTROLLED LIGHTS Because these lights can easily drain the battery if accidentally left on, many newer vehicles control these lights through computer modules. The computer module keeps track of the time the lights are on and can turn them off if the time is excessive. The computer can control either the power side or the ground side of the circuit. For example, a typical computer-controlled lighting system usually includes the following steps. STEP 1
The driver depresses or rotates the headlight switch.
STEP 2
The signal from the headlight switch is sent to the nearest control module.
STEP 3
The control module then sends a request to the headlight control module to turn on the headlights as well as the front park and side-marker lights. Through the data BUS, the rear control module receives the lights on signal and turns on the lights at the rear of the vehicle.
STEP 4
All modules monitor current flow through the circuit and will turn on a bulb failure warning light if it detects an open bulb or a fault in the circuit.
FIGURE 56–1 Dual-filament (double-contact) bulbs contain both a low-intensity filament for taillights or parking lights and a high-intensity filament for brake lights and turn signals. Bulbs come in a variety of shapes and sizes. The numbers shown are the trade numbers.
STEP 5
After the ignition has been turned off, the modules will turn off the lights after a time delay to prevent the battery from being drained.
BULB NUMBERS TRADE NUMBER The number used on automotive bulbs is called the bulb trade number, as recorded with the American National Standards Institute (ANSI). The number is the same regardless of the manufacturer. SEE FIGURE 56–1. CANDLEPOWER The trade number also identifies the size, shape, number of filaments, and amount of light produced, measured in candlepower. For example, the 1156 bulb, commonly used for backup lights, is 32 candlepower. A 194 bulb, commonly used for dash or side-marker lights, is rated at only 2 candlepower. The amount of light produced by a bulb is determined by the resistance of the filament wire, which also affects the amount of current (in amperes) required by the bulb. It is important that the correct trade number of bulb always be used for replacement to prevent circuit or component damage. The correct replacement bulb for a vehicle is usually listed in the owner or service manual. REFER TO CHART 56–1 for a listing of common bulbs and their specifications used in most vehicles. BULB NUMBER SUFFIXES Many bulbs have suffixes that indicate some feature of the bulb, while keeping the same size and light output specifications. Typical bulb suffixes include:
NA: natural amber (amber glass)
A: amber (painted glass)
HD: heavy duty
LL: long life
IF: inside frosted
L I G H T I N G AN D SI G N AL IN G C IRC U IT S
605
BULB NUMBER
AMPERAGE FILAMENTS LOW/HIGH
WATTAGE LOW/HIGH
CANDLEPOWER LOW/HIGH
4157
2
0.59/2.10
8.26/26.88
3.00/32.00
7440
1
1.75
21.00
36.60
7443
2
0.42/1.75
5.00/21.00
2.80/36.60
17131
1
0.33
4.00
2.80
17635
1
1.75
21.00
37.00
17916
2
0.42/1.75
5.00/21.00
1.20/35.00
Parking, Daytime Running Lamps
FIGURE 56–2 Bulbs that have the same trade number have the same operating voltage and wattage. The NA means that the bulb uses a natural amber glass ampoule with clear turn signal lenses.
R: red
B: blue
G: green
SEE FIGURE 56–2.
BULB NUMBER
AMPERAGE FILAMENTS LOW/HIGH
WATTAGE LOW/HIGH
CANDLEPOWER LOW/HIGH
Headlights
24
1
0.24
3.36
2.00
67
1
0.59
7.97
4.00
168
1
0.35
4.90
3.00
194
1
0.27
3.78
2.00
889
1
3.90
49.92
43.00
912
1
1.00
12.80
12.00
916
1
0.54
7.29
2.00
1034
2
0.59/1.80
8.26/23.04
3.00/32.00
1156
1
2.10
26.88
32.00
1157
2
0.59/2.10
8.26/26.88
3.00/32.00
2040
1
0.63
8.00
10.50
2057
2
0.49/2.10
6.86/26.88
1.50/24.00
2357
2
0.59/2.23
8.26/28.54
3.00/40.00
3157
2
0.59/2.10
8.26/26.88
3.00/32.00
3357
2
0.59/2.23
8.26/28.54
3.00/40.00
3457
2
0.59/2.23
8.26/28.51
3.00/40.00
3496
2
0.66/2.24
8.00/27.00
3.00/45.00
1255/H1
1
4.58
55.00
129.00
3652
1
0.42
5.00
6.00
1255/H3
1
4.58
55.00
121.00
4114
2
0.59/2/23
8.26/31.20
3.00/32.00
2
0.59/2.10
8.26/26/88
3.00/32.00
6024
2
2.73/4.69
35.00/60.00
27,000/35,000
4157
6054
2
2.73/5.08
35.00/65.00
35,000/40,000
7443
2
0.42/1.75
5.00/21.00
2.80/36.60
9003
2
4.58/5.00
55.00/60.00
72.00/120.00
17131
1
0.33
4.00
2.80
1
0.42
5.00
4.00
9004
2
3.52/5.08
45.00/65.00
56.00/95.00
17171
9005
1
5.08
65.00
136.00
17177
1
0.42
5.00
4.00
1
0.83
10.00
10.00
9006
1
4.30
55.00
80.00
17311
9007
2
4.30/5.08
55.00/65.00
80.00/107.00
17916
2
0.42/1.75
5.00/21.00
1.20/35.00
9008
2
4.30/5.08
55.00/65.00
80.00/107.00
68161
1
0.50
6.00
10.00
9011
1
5.08
65.00
163.50
Headlights (HID—Xenon)
Center High-Mounted Stop Lamp (CHMSL) 70
1
0.15
2.10
1.50
1
0.35
4.90
3.00
D2R
Air Gap
0.41
35.00
222.75
168
D2S
Air Gap
0.41
35.00
254.57
175
1
0.58
8.12
5.00
211-2
1
0.97
12.42
12.00
1
1.40
17.92
21.00
Taillights, Stop, and Turn Lamps 1156
1
2.10
26.88
32.00
577
1157
2
0.59/2.10
8.26/26.88
3.00/32.00
579
1
0.80
10.20
9.00
1
3.90
49.92
43.00
2057
2
0.49/2.10
6.86/26.88
2.00/32.00
889
3057
2
6.72/26.88
0.48/2.10
1.50/24.00
891
1
0.63
8.00
11.00
3155
1
1.60
20.48
21.00
906
1
0.69
8.97
6.00
2.20/24.00
912
1
1.00
12.80
12.00
921
1
1.40
17.92
21.00
922
1
0.98
12.54
15.00
1141
1
1.44
18.43
21.00
3157
2
0.59/2.10
8.26/26.88
CHART 56–1 Bulbs that have the same trade number have the same operating voltage and wattage. The NA means that the bulb uses a natural amber glass ampoule with clear turn signal lenses.
606
CHAPTER 5 6
CONTINUED
BULB NUMBER
AMPERAGE FILAMENTS LOW/HIGH
WATTAGE LOW/HIGH
CANDLEPOWER LOW/HIGH
BULB NUMBER
AMPERAGE FILAMENTS LOW/HIGH
WATTAGE LOW/HIGH
CANDLEPOWER LOW/HIGH
17177 1 0.42 17314 1 0.83 17916 2 0.42/1.75 47830 1 0.39 Instrument Panel 37 1 0.09 73 1 0.08 74 1 0.10 PC74 1 0.10 PC118 1 0.12 124 1 0.27 158 1 0.24 161 1 0.19 192 1 0.33 194 1 0.27 PC194 1 0.27 PC195 1 0.27 1210/H1 1 8.33 1210/H3 1 8.33 17037 1 0.10 17097 1 0.25 17314 1 0.83 Backup, Cornering, Fog/Driving Lamps 67 1 0.59 579 1 0.80 880 1 2.10 881 1 2.10 885 1 3.90 886 1 3.90 893 1 2.93 896 1 2.93 898 1 2.93 899 1 2.93 921 1 1.40 1073 1 1.80 1156 1 2.10 1157 2 0.59/2.10 1210/H1 1 8.33 1255/H1 1 4.58 1255/H3 1 4.58 1255/H11 1 4.17 2057 2 0.49/2.10 3057 2 0.48/2.10 3155 1 1.60 3156 1 2.10 3157 2 0.59/2.10 4157 2 0.59/2.10 7440 1 1.75 9003 2 4.58/5.00 9006 1 4.30 9145 1 3.52 17635 1 1.75
5.00 10.00 5.00/21.00 5.00
4.00 8.00 1.20/35.00 6.70
1.26 1.12 1.40 1.40 1.68 3.78 3.36 2.66 4.29 3.78 3.78 3.78 100.00 100.00 1.20 3.00 10.00
0.50 0.30 0.70 0.70 0.70 1.50 2.00 1.00 3.00 2.00 2.00 1.80 217.00 192.00 0.48 1.76 8.00
7.97 10.20 26.88 26.88 49.92 49.92 37.50 37.50 37.50 37.50 17.92 23.04 26.88 8.26/26.88 100.00 55.00 55.00 55.00 6.86/26.88 6.72/26.88 20.48 26.88 8.26/26.88 8.26/26/88 21.00 55.00/60.00 55.00 45.00 21.00
4.00 9.00 43.00 43.00 100.00 100.00 75.00 75.00 60.00 60.00 21.00 32.00 32.00 3.00/32.00 217.00 129.00 121.00 107.00 1.50/24.00 2.00/32.00 21.00 32.00 3.00/32.00 3.00/32.00 36.00 72.00/120.00 80.00 65.00 37.00
1156
1
2.10
26.88
32.00
2723
1
0.20
2.40
1.50
3155
1
1.60
20.48
21.00
3156
1
2.10
26.88
32.00
3497
1
2.24
27.00
45.00
7440
1
1.75
21.00
36.60
17177
1
0.42
5.00
4.00
17635
1
1.75
21.00
37.00
License Plate, Glove Box, Dome, Side Marker, Trunk, Map, Ashtray, Step/Courtesy, Underhood 37
1
0.09
1.26
0.50
67
1
0.59
7.97
4.00
74
1
0.10
1.40
.070
98
1
0.62
8.06
6.00
105
1
1.00
12.80
12.00
124
1
0.27
3.78
1.50
161
1
0.19
2.66
1.00
168
1
0.35
4.90
3.00
192
1
0.33
4.29
3.00
194
1
0.27
3.78
2.00
211-1
1
0.968
12.40
12.00
212-2
1
0.74
9.99
6.00
214-2
1
0.52
7.02
4.00
293
1
0.33
4.62
2.00
561
1
0.97
12.42
12.00
562
1
0.74
9.99
6.00
578
1
0.78
9.98
9.00
579
1
0.80
10.20
9.00
PC579
1
0.80
10.20
9.00
906
1
0.69
8.97
6.00
912
1
1.00
12.80
12.00
917
1
1.20
14.40
10.00
921
1
1.40
17.92
21.00
1003
1
0.94
12.03
15.00
1155
1
0.59
7.97
4.00
1210/H2
1
8.33
100.00
239.00
1210/H3
1
8.33
100.00
192.00
1445
1
0.14
2.02
0.70
1891
1
0.24
3.36
2.00
1895
1
0.27
3.78
2.00
3652
1
0.42
5.00
6.00
11005
1
0.39
5.07
4.00
11006
1
0.24
3.36
2.00
12100
1
0.77
10.01
9.55
13050
1
0.38
4.94
3.00
17036
1
0.10
1.20
0.48
17097
1
0.25
3.00
1.76
17131
1
0.33
4.00
2.80 CONTINUED
L I G H T I N G AN D SI G N AL IN G C IRC U IT S
607
FIGURE 56–3 Close-up a 2057 dual-filament (double-contact) bulb that failed. Notice that the top filament broke from its mounting and melted onto the lower filament. This bulb caused the dash lights to come on whenever the brakes were applied.
FIGURE 56–4 Corrosion caused the two terminals of this dualfilament bulb to be electrically connected.
REAL WORLD FIX Weird Problem—Easy Solution A General Motors minivan had the following electrical problems. • The turn signals flashed rapidly on the left side. • With the ignition key off, the lights-on warning chime sounded if the brake pedal was depressed. • When the brake pedal was depressed, the dome light came on. All of these problems were caused by one defective 2057 dual-filament bulb, as shown in FIGURE 56–3. Apparently, the two filaments were electrically connected when one filament broke and then welded to the other filament. This caused the electrical current to feed back from the brake light filament into the taillight circuit, causing all the problems.
TESTING BULBS
Bulbs can be tested using two basic tests.
1. Perform a visual inspection of any bulb. Many faults, such as a shorted filament, corroded connector, or water, can cause weird problems that are often thought to be wiring issues.
SEE FIGURES 56–4 AND 56–5.
608
CHAPTER 5 6
FIGURE 56–5 Often the best diagnosis is a thorough visual inspection. This bulb was found to be filled with water, which caused weird problems.
FIGURE 56–6 This single-filament bulb is being tested with a digital multimeter set to read resistance in ohms. The reading of 1.1 ohms is the resistance of the bulb when cold. As soon as current flows through the filament, the resistance increases about 10 times. It is the initial surge of current flowing through the filament when the bulb is cool that causes many bulbs to fail in cold weather as a result of the reduced resistance. As the temperature increases, the resistance increases. 2. Bulbs can be tested using an ohmmeter and checking the resistance of the filaments(s). Most bulbs will read low resistance at room temperature between 0.5 and 20 ohms depending on the bulb. Test results include:
Normal resistance. The bulb is good. Check both filaments if it is a two-filament bulb. SEE FIGURE 56–6. Zero ohms. It is unlikely but possible for the bulb filament to be shorted. OL (electrically open). The reading indicates that the bulb filament is broken.
BRAKE LIGHTS OPERATION Brake lights, also called stop lights, use the highintensity filament of a double-filament bulb. (The low-intensity filament is for the taillights.) When the brakes are applied, the brake switch is closed and the brake lamps light. The brake switch receives current from a fuse that is hot all the time. The brake light switch is a normally open (N.O.) switch, but is closed when the driver depresses the brake
HOT AT ALL TIMES
HOT IN RUN, BULB TEST OR START
SEE POWER DISTRIBUTION 1 DK BLK
FUSE BLOCK
TURN B/U FUSE 20 AMP
SEE POWER DISTRIBUTION
STOP HAZ FUSE 20 AMP
FUSE BLOCK
.8 ORN
75
1 DK BLK
BACK UP LIGHTS
75
140
B
1 DK BLU H3
75
W
TURN FLASHER
C205
HAZARD FLASHER
.5 ORN B
140 BRAKE SWITCH CLOSED WITH BRAKE PEDAL DEPRESSED
CONVENIENCE CENTER
(NOT USED) A
A
.8 PPL L PPL
V .8 BRN
16
K BRN
16
HAZARD SWITCH NORMAL
27 C201
1 WHT
27 TURN/ HAZARD SWITCH
HAZARD
17 H
820 C204
.8 LT BLU/ BLK A
820
.8 LT BLU
820
A
P
WHT
C .8 LT BLU/ BLK M 17
C324
C318 HIGH LEVEL STOP LIGHT
C201
LT BLU
C201 14 M .8 YEL
.8 14 LT BLU
D 1 YEL A 1 YEL
1 YEL 18 LH
LH
DK GRN N
18 .8 DK GRN
E 18 1 DK GRN 1 DK GRN
B
19 19 C204 19 C325 19
18
RH
15
DK BLU
C201
J
C201
C318
.8 BLK B
150 C324
1 BLK
150 S317
1 DK GRN 19
RH
15
.8 DK BLU
TAIL/STOPTURN LIGHTS STOPTURN .8 BLK
TAIL 150
STOPTURN .8 BLK
TAIL 150
S403 .3 BLK C SEE GROUND DISTRIBUTION
150 C325
.8 BLK
STOPTURN .8 BLK
150 SEE GROUND DISTRIBUTION
TAIL 150 S404
STOPTURN .8 BLK
TAIL 150 B
G200
FIGURE 56–7 Typical brake light and taillight circuit showing the brake switch and all of the related circuit components. pedal. Since 1986, all vehicles sold in the United States have a third brake light commonly referred to as the center high-mounted stop light (CHMSL). SEE FIGURE 56–7.
?
FREQUENTLY ASKED QUESTION
Why Are LEDs Used for Brake Lights? Light-emitting diode (LED) brake lights are frequently used for high-mounted stop lamps (CHMSLs) for the following reasons. 1. Faster illumination. An LED will light up to 200 milliseconds faster than an incandescent bulb, which requires some time to heat the filament before it is hot enough to create light. This faster illumination can mean the difference in stopping distances at 60 mph (100 km/h) by about 18 ft (6 m) due to the reduced reaction time for the driver of the vehicle behind. 2. Longer service life. LEDs are solid-state devices that do not use a filament to create light. As a result, they are less susceptible to vibration and will often last the life of the vehicle. NOTE: Aftermarket replacement LED bulbs that are used to replace conventional bulbs may require the use of a different type of flasher unit due to the reduced current draw of the LED bulbs. SEE FIGURE 56–8.
FIGURE 56–8 A replacement LED taillight bulb is constructed of many small, individual light-emitting diodes. The brake switch is also used as an input switch (signal) for the following: 1. Cruise control (deactivates when the brake pedal is depressed) 2. Antilock brakes (ABS) 3. Brake shift interlock (prevents shifting from park position unless the brake pedal is depressed)
L I G H T I N G AN D SI G N AL IN G C IRC U IT S
609
RIGHT TURN CANCELLING SPRING
MOUNTING SCREWS
L
R
L
FRONT TURN
HAZARD
G
DIRECTIONAL LEVER
HORN CONTACT LEFT TURN CANCELLING SPRING
FIGURE 56–9 The typical turn signal switch includes various springs and cams to control the switch and to cause the switch to cancel after a turn has been completed.
H
J
K
L
R
L
REAR TURN
LEFT STOP
R
L
R RIGHT STOP
TS OVERRIDE
M
N
P
FROM BRAKE SWITCH TO RIGHT BRAKE LAMP TO LEFT BRAKE LAMP FROM TURN SIGNAL FLASHER FROM HAZARD FLASHER TO RIGHT TURN LAMPS TO LEFT TURN LAMPS
FIGURE 56–10 When the stop lamps and turn signals share a common bulb filament, stop light current flows through the turn signal switch.
TURN SIGNALS L
OPERATION
TWO-FILAMENT STOP/TURN BULBS In systems using separate filaments for the stop and turn lamps, the brake and turn signal switches are not connected. If the vehicle uses the same filament for both purposes, then brake switch current is routed through contacts within the turn signal switch. By linking certain contacts, the bulbs can receive either brake switch current or flasher current, depending upon which direction is being signaled. For
610
CHAPTER 5 6
L
FRONT TURN
The turn signal circuit is supplied power from the ignition switch and operated by a lever and switch. SEE FIGURE 56–9. When the turn signal switch is moved in either direction, the corresponding turn signal lamps receive current through the flasher unit. The flasher unit causes the current to start and stop as the turn signal lamp flashes on and off with the interrupted current.
ONE-FILAMENT STOP/TURN BULBS In many vehicles, the stop and turn signals are both provided by one filament. When the turn signal switch is turned on (closed), the filament receives interrupted current through the flasher unit. When the brakes are applied, the current first flows to the turn signal switch, except for the highmounted stop, which is fed directly from the brake switch. If neither turn signal is on, then current through the turn signal switch flows to both rear brake lights. If the turn signal switch is operated (turned to either left or right), current flows through the flasher unit on the side that was selected and directly to the brake lamp on the opposite side. If the brake pedal is not depressed, then current flows through the flasher and only to one side. SEE FIGURE 56–10. Moving the lever up or down completes the circuit through the flasher unit and to the appropriate turn signal lamps. A turn signal switch includes cams and springs that cancel the signal after the turn has been completed. As the steering wheel is turned in the signaled direction and then returns to its normal position, the cams and springs cause the turn signal switch contacts to open and break the circuit.
R
HAZARD
G
H
J
K
L
M
R
L
REAR TURN
R LEFT STOP
L
R RIGHT STOP
TS OVERRIDE
N
P
STEADY CURRENT FLOW FROM BRAKE SWITCH TO LEFT BRAKE LAMP INTERRUPTED CURRENT FLOW FROM TURN SIGNAL FLASHER TO RIGHT BRAKE LAMPS
FIGURE 56–11 When a right turn in signaled, the turn signal switch contacts send flasher current to the right-hand filament and brake switch current to the left-hand filament.
example, FIGURE 56–11 shows current flow through the switch when the brake switch is closed and a right turn is signaled. Steady current through the brake switch is sent to the left brake lamp. Interrupted current from the turn signal is sent to the right turn lamps.
FLASHER UNITS A turn signal flasher unit is a metal or plastic can containing a switch that opens and closes the turn signal circuit. Vehicles can be equipped with many different types of flasher units. SEE FIGURE 56–12.
DOT flashers. This turn signal flasher unit is often installed in a metal clip attached to the dash panel to allow the “clicking” noise of the flasher to be heard by the driver. The turn signal flasher is designed to transmit the current to light the front and rear bulbs on only one side at a time. The U.S. Department of Transportation (DOT) regulation requires that the driver be
FIGURE 56–12 Two styles of two-prong flasher units.
alerted when a turn signal bulb is not working. This is achieved by using a series-type flasher unit. The flasher unit requires current flow through two bulbs (one in the front and one in the rear) in order to flash. If one bulb burns out, the current flow through only one bulb is not sufficient to make the unit flash; it will be a steady light. These turn signal units are often called DOT flashers.
Bimetal flashers. The bimetal flashers have a lower cost and shorter life expectancy than hybrid or solid-state flashers. The operation of this flasher is current sensitive, which means that the flasher will stop flashing when one of the light bulbs is out and that it will flash at a faster rate when adding additional load, such as a trailer. The bimetal element is a sandwich of two different metals that distorts with temperature changes similar to a circuit breaker. The turn signal lamp current is passed through the bimetal element and causes heating. When the element is hot enough, the bimetal distorts, opening the contacts and turning off the lamps. After the bimetal cools, it returns to the original shape, closing the contacts and turning on the lamps again. This sequence is repeated until the load is removed. If one bulb burns out, the turn signal indicator lamp on the dash will remain lighted. The flasher will not flash because there is not enough current flow through the one remaining bulb to cause the flasher to become heated enough to open.
Hybrid flashers. The hybrid flashers have an electronic flasher control circuit to operate the internal electromechanical relay and are commonly called a flasher relay. This type of flasher has a stable electronic timing circuitry that enables a wide operating voltage and temperature range with a reasonable cost. The life expectancy is considerably longer compared to bimetal units and is dependent on the load and relay used internally for switching the load. The hybrid flasher has a lamp current-sensing circuit which will cause the flash rate to double when a bulb is burned out.
Solid-state flashers. The solid-state flashers have an internal electronic circuit for timing and solid-state power output devices for load switching. Life expectancy is longer than other flashers because there are no moving parts for mechanical breakdown. The biggest disadvantage of solid state is the higher cost. Solid-state units cause the turn indicator to flash rapidly if a bulb is burned out.
ELECTRONIC FLASHER REPLACEMENT UNITS
Older vehicles (and a few newer ones) use thermal (bimetal) flashers that use heat to switch on and off. Most turn signal flasher units are mounted in a metal clip that is attached to the dash. The dash panel acts as a sounding board, increasing the sound of the flasher unit.
FIGURE 56–13 A hazard warning flasher uses a parallel resistor across the contacts to provide a constant flashing rate regardless of the number of bulbs used in the circuit. Most four-way hazard flasher units are plugged into the fuse panel. Some turn signal flasher units are plugged into the fuse panel. How do you know for sure where the flasher unit is located? With both the turn signal and the ignition on, listen and/or feel for the clicking of the flasher unit. Some service manuals also give general locations for the placement of flasher units. Newer vehicles have electronic flashers that use microchips to control the on/off function. Electronic flashers are compatible with older systems and are wise to use for the following reasons. 1. Electronic flashers do not burn out, and they provide a faster “flash” of the turn signals. 2. If upgrading to LED tail lamps, or lights, the LED bulbs only work with electronic flashers unless a resistor is added in the circuit.
HAZARD WARNING FLASHER
The hazard warning flasher is a device installed in a vehicle lighting system with the primary function of causing both the left and right turn signal lamps to flash when the hazard warning switch is activated. Secondary functions may include visible dash indicators for the hazard system and an audible signal to indicate when the flasher is operating. A typical hazard warning flasher is also called a parallel or variable-load flasher because there is a resistor in parallel with the contacts to provide a control load and, therefore, a constant flash rate, regardless of the number of bulbs being flashed. SEE FIGURE 56–13.
COMBINATION TURN SIGNAL AND HAZARD WARNING FLASHER The combination flasher is a device that combines the functions of a turn signal flasher and a hazard warning flasher into one package, which often uses three electrical terminals.
HEADLIGHTS HEADLIGHT SWITCHES
The headlight switch operates the exterior and interior lights of most vehicles. On noncomputer-controlled lighting systems, the headlight switch is connected directly to the
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611
IGNITION SWITCH
FUSIBLE LINK
12 V B
20 A
L
Y LEFT TURN
TURN SIGNAL SWITCH
FLASHER UNIT
1.5 Ω
HEADLIGHT SWITCH
R
DASH SIDE MARKER LIGHT
FIGURE 56–14 The side-marker light goes out whenever there is voltage at both points X and Y. These opposing voltages stop current flow through the side-marker light. The left turn light and left park light are actually the same bulb (usually 2057) and are shown separately to help explain how the side-marker light works on many vehicles.
X PARK LIGHT
6Ω
?
HOT AT ALL TIMES
FREQUENTLY ASKED QUESTION
How Do You Tell What Type of Flasher Is Being Used? The easiest way to know which type of flasher can be used is to look at the type of bulb used in the tail lamps and turn signals. If it is a “wedge” style (plastic base, flat and rectangular), the vehicle has an electronic flasher. If it is a “twist and turn” bayonet-style (brass base) bulb, then either type of flasher can be used.
?
HEADLIGHT HEAD SWITCH
15 R/Y C303 MULTIFUNCTION STEERING COLUMNMOUNTED SWITCH
HI
DIMMER SWITCH LO
C303
FREQUENTLY ASKED QUESTION HIGH-BEAM INDICATOR LIGHT
A question that service technicians are asked frequently is why the side-marker light alternately goes out when the turn signal is on, and is on when the turn signal is off. Some vehicle owners think that there is a fault with the vehicle, but this is normal operation. The side-marker light goes out when the lights are on and the turn signal is flashing because there are 12 volts on both sides of the bulb (see points X and Y in FIGURE 56–14). Normally, the side-marker light gets its ground through the turn signal bulb.
battery through a fusible link, and has continuous power or is “hot” all the time. A circuit breaker is built into most older model headlight switches to protect the headlight circuit. SEE FIGURE 56–15. The headlight switch may include the following: The interior dash lights can often be dimmed manually by rotating the headlight switch knob or by another rotary knob that controls a variable resistor (called a rheostat). The rheostat drops the voltage sent to the dash lights. Whenever there is a voltage drop (increased resistance), there is heat. A coiled resistance wire is built into a ceramic housing that is designed to insulate the rest of the switch from the heat and allow heat to escape.
612
C270
OFF PARK
Why Does the Side-Marker Light Alternately Flash?
38 BK/O
CIRCUIT BREAKER
CHAPTER 5 6
13 R/BR S-132
13 R/BK
12
13 R/BK
LG/BR LEFT DUAL BEAM
57 BK G302
57 BK G402
LEFT HIGH BEAM
RIGHT HIGH BEAM
RIGHT DUAL BEAM
57 BK G401
FIGURE 56–15 Typical headlight circuit diagram. Note that the headlight switch is represented by a dotted outline indicating that other circuits (such as dash lights) also operate from the switch.
The headlight switch also contains a built-in circuit breaker that will rapidly turn the headlights on and off in the event of a short circuit. This prevents a total loss of headlights. If the headlights are rapidly flashing on and off, check the entire headlight circuit for possible shorts. The circuit breaker controls only the headlights. The other lights controlled by the headlight switch (taillights, dash lights, and parking lights) are fused separately. Flashing headlights also may be caused by a failure in the builtin circuit breaker, requiring replacement of the switch assembly.
FIGURE 56–16 A typical four-headlight system using sealed beam headlights.
FIGURE 56–17 A typical composite headlamp assembly. The lens, housing, and bulb sockets are usually included as a complete assembly.
AUTOMATIC HEADLIGHTS
Computer-controlled lights use a light sensor that signals when to have the computer turn on the headlights. The sensor is mounted on the dashboard or mirror. Often these systems have a driver-adjusted sensitivity control that allows for the lights to be turned on at various levels of light. Most systems also have a computer module control over the time that the lights remain on after the ignition has been turned off and the last door has been closed. A scan tool is often needed to change this time delay.
SEALED BEAM HEADLIGHTS A sealed beam headlight consists of a sealed glass or plastic assembly containing the bulb, reflective surface, and prism lenses to properly focus the light beam. Low-beam headlights contain two filaments and three electrical terminals.
One for low beam
One for high beam
Common ground
High-beam headlights contain only one filament and two terminals. Because low-beam headlights also contain a high-beam filament, the entire headlight assembly must be replaced if either filament is defective. SEE FIGURE 56–16. A sealed beam headlight can be tested with an ohmmeter. A good bulb should indicate low ohms between the ground terminal and both power-side (hot) terminals. If either the high-beam or the lowbeam filament is burned out, the ohmmeter will indicate infinity (OL).
HALOGEN SEALED BEAM HEADLIGHTS
Halogen sealed beam headlights are brighter and more expensive than normal headlights. Because of their extra brightness, it is common practice to have only two headlights on at any one time, because the candlepower output would exceed the maximum U.S. federal standards if all four halogen headlights were on. Therefore, before trying to repair the problem that only two of the four lamps are on, check the owner or shop manual for proper operation. CAUTION: Do not attempt to wire all headlights together. The extra current flow could overheat the wiring from the headlight switch through the dimmer switch and to the headlights. The overloaded circuit could cause a fire.
COMPOSITE HEADLIGHTS
Composite headlights are constructed using a replaceable bulb and a fixed lens cover that is part of the vehicle. Composite headlights are the result of changes in the aerodynamic styling of vehicles where sealed beam lamps could no longer be used. SEE FIGURE 56–17.
FIGURE 56–18 Handle a halogen bulb by the base to prevent the skin’s oil from getting on the glass. TECH TIP Diagnose Bulb Failure Halogen bulbs can fail for various reasons. Some causes for halogen bulb failure and their indications are as follows: • Gray color. Low voltage to bulb (check for corroded socket or connector) • White (cloudy) color. Indication of an air leak • Broken filament. Usually caused by excessive vibration • Blistered glass. Indication that someone has touched the glass NOTE: Never touch the glass (called the ampoule) of any halogen bulb. The oils from your fingers can cause unequal heating of the glass during operation, leading to a shorter-than-normal service life. SEE FIGURE 56–18.
The replaceable bulbs are usually bright halogen bulbs. Halogen bulbs get very hot during operation, between 500°F and 1,300°F (260°C and 700°C). It is important never to touch the glass of any halogen bulb with bare fingers because the natural oils of the skin on the glass bulb can cause the bulb to break when it heats during normal operation.
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SOCKET
BULB
IGNITOR
FIGURE 56–19 The igniter contains the ballast and transformer needed to provide high-voltage pulses to the arc tube bulb.
?
FREQUENTLY ASKED QUESTION
What Is the Difference Between the Temperature of the Light and the Brightness of the Light? The temperature of the light indicates the color of the light. The brightness of the light is measured in lumens. A standard 100 watt incandescent light bulb emits about 1,700 lumens. A typical halogen headlight bulb produces about 2,000 lumens, and a typical HID bulb produces about 2,800 lumens.
FIGURE 56–20 HID (xenon) headlights emit a whiter light than halogen headlights and usually look blue compared to halogen bulbs. The HID ballast is powered by 12 volts from the headlight switch on the body control module. The HID headlights operate in three stages or states. 1. Start-up or stroke state 2. Run-up state 3. Steady state
START-UP OR STROKE STATE
When the headlight switch is turned to the on position, the ballast may draw up to 20 amperes at 12 volts. The ballast sends multiple high-voltage pulses to the arc tube to start the arc inside the bulb. The voltage provided by the ballast during the start-up state ranges from ⫺600 volts to ⫹600 volts, which is increased by a transformer to about 25,000 volts. The increased voltage is used to create an arc between the electrodes in the bulb.
RUN-UP STATE
HIGH-INTENSITY DISCHARGE HEADLIGHTS PARTS AND OPERATION
High-intensity discharge (HID) headlights produce a distinctive blue-white light that is crisper, clearer, and brighter than light produced by a halogen headlight. High-intensity discharge lamps do not use a filament like conventional electrical bulbs, but contain two electrodes about 0.2 in. (5 mm) apart. A high-voltage pulse is sent to the bulb which arcs across the tips of electrodes producing light. It creates light from an electrical discharge between two electrodes in a gas-filled arc tube. It produces twice the light with less electrical input than conventional halogen bulbs. The HID lighting system consists of the discharge arc source, igniter, ballast, and headlight assembly. SEE FIGURE 56–19. The two electrodes are contained in a tiny quartz capsule filled with xenon gas, mercury, and metal halide salts. HID headlights are also called xenon headlights. The lights and support electronics are expensive, but they should last the life of the vehicle unless physically damaged. HID headlights produce a white light giving the lamp a bluewhite color. The color of light is expressed in temperature using the Kelvin scale. Kelvin (K) temperature is the Celsius temperature plus 273 degrees. Typical color temperatures include:
Daylight: 5,400°K
HID: 4,100°K
Halogen: 3,200°K
Incandescent (tungsten): 2,800°K
SEE FIGURE 56–20.
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After the arc is established, the ballast provides a higher than steady state voltage to the arc tube to keep the bulb illuminated. On a cold bulb, this state could last as long as 40 seconds. On a hot bulb, the run-up state may last only 15 seconds. The current requirements during the run-up state are about 360 volts from the ballast and a power level of about 75 watts.
STEADY STATE The steady state phase begins when the power requirement of the bulb drops to 35 watts. The ballast provides a minimum of 55 volts to the bulb during steady state operation. BI-XENON HEADLIGHTS Some vehicles are equipped with bixenon headlights, which use a shutter to block some of the light during low-beam operation and then mechanically move to expose more of the light from the bulb for high-beam operation. Because xenon lights are relatively slow to start working, vehicles equipped with bi-xenon headlights use two halogen lights for the “flash-to-pass” feature. FAILURE SYMPTOMS
The following symptoms indicate bulb
failure.
A light flickers
Lights go out (caused when the ballast assembly detects repeated bulb restrikes)
Color changes to a dim pink glow
Bulb failures are often intermittent and difficult to repeat. However, bulb failure is likely if the symptoms get worse over time. Always follow the vehicle manufacturer’s recommended testing and service procedures.
DIAGNOSIS AND SERVICE High-intensity discharge headlights will change slightly in color with age. This color shift is usually not noticeable unless one headlight arc tube assembly has been replaced due to a collision repair, and then the difference in color may be noticeable. The difference in color will gradually change as
the arc tube ages and should not be too noticeable by most customers. If the arc tube assembly is near the end of its life, it may not light immediately if it is turned off and then back on immediately. This test is called a “hot restrike” and if it fails, a replacement arc tube assembly may be needed or there is another fault, such as a poor electrical connection, that should be checked.
WARNING
HEADLIGHT AIMING According to U.S. federal law, all headlights, regardless of shape, must be able to be aimed using headlight aiming equipment. Older vehicles equipped with sealed beam headlights used a headlight aiming system that attached to the headlight itself. SEE FIGURES 56–22 AND 56–23. Also see the photo sequence on headlight aiming at the end of the chapter.
Always adhere to all warnings because the highvoltage output of the ballast assembly can cause personal injury or death.
LED HEADLIGHTS Some vehicles, including several Lexus models, use LED headlights either as standard equipment (Lexus LS600h) or optional. SEE FIGURE 56–21. Advantages include:
Long service life
Reduced electrical power required Disadvantages include:
High cost
Many small LEDs required to create the necessary light output
FIGURE 56–21 LED headlights usually require multiple units to provide the needed light as seen on this Lexus LS600h.
12 FEET (3.6 m) MINIMUM
DISTANCE BETWEEN HEADLAMPS
ADJUSTABLE VERTICAL TAPES CENTER LINE OF SCREEN HORIZONTAL CENTER LINE OF LAMPS ADJUSTABLE HORIZONTAL TAPES
VEHICLE AXIS
25 FEET (7.6 m) DIAGRAM OF LIGHT SCREEN
PAINTED REFERENCE LINE ON SHOP FLOOR
VERTICAL CENTERLINE AHEAD OF LEFT HEADLAMP
VEHICLE VERTICAL CENTERLINE AXIS AHEAD OF RIGHT HEADLAMP
VERTICAL CENTERLINE AHEAD OF LEFT HEADLAMP
HEIGHT OF LAMP CENTERS
HIGH INTENSITY AREA
HIGH INTENSITY AREA
ADJUSTING PATTERN FOR LOW BEAM
HIGH INTENSITY AREA
VEHICLE AXIS
VERTICAL CENTERLINE AHEAD OF RIGHT HEADLAMP HEIGHT OF LAMP CENTERS
HIGH INTENSITY AREA
ADJUSTING PATTERN FOR HIGH BEAM
FIGURE 56–22 Typical headlight aiming diagram as found in service information. L I G H T I N G AN D SI G N AL IN G C IRC U IT S
615
LEVELING MOTOR LOW BEAM HEADLIGHT
STEERING ANGLE VEHICLE HEIGHT
AFS ECU
VEHICLE SPEED
SWIVEL MOTOR
FIGURE 56–23 Many composite headlights have a built-in bubble level to make aiming easy and accurate.
IN RIGHT TURNS: ROTATES UP TO 5˚
STRAIGHT AHEAD
IN LEFT TURNS: ROTATES UP TO 15˚
FIGURE 56–24 Adaptive front lighting systems rotate the low-beam headlight in the direction of travel.
ADAPTIVE FRONT LIGHTING SYSTEM PARTS AND OPERATION
A system that mechanically moves the headlights to follow the direction of the front wheels is called adaptive (or advanced) front light system, or AFS. The AFS provides a wide range of visibility during cornering. The headlights are usually capable of rotating 15 degrees to the left and 5 degrees to the right (some systems rotate 14 degrees and 9 degrees, respectively). Vehicles that use AFS include Lexus, Mercedes, and certain domestic models, usually as an extra cost option. SEE FIGURE 56–24. NOTE: These angles are reversed on vehicles sold in countries that drive on the left side of the road, such as Great Britain, Japan, Australia, and New Zealand. The vehicle has to be moving above a predetermined speed, usually above 20 mph (30 km/h) and the lights stop moving when the speed drops below about 3 mph (5 km/h). AFS is often used in addition to self-leveling motors so that the headlights remain properly aimed regardless of how the vehicle is loaded. Without self-leveling, headlights would shine higher
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FIGURE 56–25 A typical adaptive front lighting system uses two motors: one for the up and down movement and the other for rotating the low-beam headlight to the left and right.
FIGURE 56–26 Typical dash-mounted switch that allows the driver to disable the front lighting system.
than normal if the rear of the vehicle is heavily loaded. SEE FIGURE 56–25. When a vehicle is equipped with an adaptive front lighting system, the lights are moved by the headlight controller outward, and then inward as well as up and down as a test of the system. This action is quite noticeable to the driver, and is normal operation of the system.
DIAGNOSIS AND SERVICE The first step when diagnosing an AFS fault is to perform the following visual inspection.
Start by checking that the AFS is switched on. Most AFS headlights are equipped with a switch that allows the driver to turn the system on and off. SEE FIGURE 56–26.
Check that the system performs a self-test during start-up.
Verify that both low-beam and high-beam lights function correctly. The system may be disabled if a fault with one of the headlights is detected.
Use a scan tool to test for any AFS-related diagnostic trouble codes. Some systems allow the AFS to be checked and operated using a scan tool.
Always follow the recommended testing and service procedures as specified by the vehicle manufacturer in service information.
TECH TIP
COURTESY LIGHTS
Checking a Dome Light Can Be Confusing If a technician checks a dome light with a test light, both sides of the bulb will “turn on the light” if the bulb is good. This will be true if the system’s “ground switched” doors are closed and the bulb is good. This confuses many technicians because they do not realize that the ground will not be sensed unless the door is open.
Courtesy light is a generic term primarily used for interior lights, including overhead (dome) and under-the-dash (courtesy) lights. These interior lights are controlled by operating switches located in the doorjambs of the vehicle doors or by a switch on the dash. SEE FIGURE 56–29. Many Ford vehicles use the door switches to open and close the power side of the circuit. Many newer vehicles operate the interior lights through the vehicle computer or through an electronic module. Because the exact wiring and operation of these units differ, consult the service information for the exact model of the vehicle being serviced.
DAYTIME RUNNING LIGHTS PURPOSE AND FUNCTION
Daytime running lights (DRLs)
ILLUMINATED ENTRY
involve operation of the following:
Front parking lights
Separate DRL lamps
Headlights (usually at reduced current and voltage) when the vehicle is running
Canada has required daytime running lights on all new vehicles since 1990. Studies have shown that DRLs have reduced accidents where used. Daytime running lights primarily use a control module that turns on either the low or high-beam headlights or separate daytime running lights. The lights on some vehicles come on when the engine starts. Other vehicles will turn on the lamps when the engine is running but delay their operation until a signal from the vehicle speed sensor indicates that the vehicle is moving. To avoid having the lights on during servicing, some systems will turn off the headlights when the parking brake is applied and the ignition switch is cycled off then back on. Others will only light the headlights when the vehicle is in a drive gear. SEE FIGURE 56–27. CAUTION: Most factory daytime running lights operate the headlights at reduced intensity. These are not designed to be used at night. Normal intensity of the headlights (and operation of the other external lamps) is actuated by turning on the headlights as usual.
Some vehicles are equipped with illuminated entry, meaning the interior lights are turned on for a given amount of time when the outside door handle is operated while the doors are locked. Most vehicles equipped with illuminated entry also light the exterior door keyhole. Vehicles equipped with body computers use the input from the key fob remote to “wake up” the power supply for the body computer.
FIBER OPTICS Fiber optics is the transmission of light through special plastic (polymethyl methacrylate) that keeps the light rays parallel even if the plastic is tied in a knot. These strands of plastic are commonly used in automotive applications as indicators for the driver that certain lights are functioning. For example, some vehicles are equipped with fender-mounted units that light when the lights or turn signals are operating. Plastic fiber-optic strands, which often look like standard electrical wire, transmit the light at the bulb to the indicator on top of the fender so that the driver can determine if a certain light is operating. Fiber-optic strands also can be run like wires to indicate the operation of all lights on the dash or console. Fiber-optic strands are also commonly used to light ashtrays, outside door locks, and other areas where a small amount of light is required. The source of the light can be any normally operating light bulb, which means that one bulb can be used to illuminate many areas. A special bulb clip is normally used to retain the fiber-optic plastic tube near the bulb.
DIMMER SWITCHES The headlight switch controls the power or hot side of the headlight circuit. The current is then sent to the dimmer switch, which allows current to flow to either the high-beam or the low-beam filament of the headlight bulb, as shown in FIGURE 56–28. An indicator light illuminates on the dash when the high beams are selected. The dimmer switch is usually hand operated by a lever on the steering column. Some steering column switches are actually attached to the outside of the steering column and are spring loaded. To replace these types of dimmer switches, the steering column needs to be lowered slightly to gain access to the switch itself.
AUTOMATIC DIMMING MIRRORS PARTS AND OPERATION
Automatic dimming mirrors use electrochromic technology to dim the mirror in proportion to the amount of headlight glare from other vehicles at the rear. The electrochromic technology developed by Gentex Corporation uses a gel that changes with light between two pieces of glass. One piece of glass acts as a reflector and the other has a transparent (clear) electrically conductive coating. The inside rearview mirror also has
L I G H T I N G AN D SI G N AL IN G C IRC U IT S
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HOT AT ALL TIMES
TAIL LPS FUSE 20 AMP
HDLP CIRCUIT BEAKER 20 AMP
1 ORN
640
1 ORN
240
B
C1
F
1DK BLU/WHT
593
1 YEL
640
F
C1 TURN/ HAZARD HEADLIGHT SWITCH ASSEMBLY
HEADLIGHT SWITCH HEAD
OFF
OFF
PARK
E 1 BRN
A
HEAD PARK HEADLIGHT 1 ORN DIMMER SWITCH
LO
HI
C
B
1 TAN
9 1 YEL
C1
A .8 BRN
D
1 ORN
D
CONTACT CLOSED IN NIGHT MODE FRONT/TAIL LIGHTS ON ENABLE
CONTACT CLOSED IN DAY MODE DRL HEADLIGHTS ON ENABLE
240
1 ORN
DAYTIME RUNNING LIGHTS (DRL) MODULE
CONTACT CLOSED IN NIGHT MODE HEADLIGHTS ON ENABLE
E
FUSE BLOCK
C1
12
10
1 LT GRN
11
1 LT GRN
11
S206
9
P101
FRONT TAIL/LIGHTS
10
2
C101
3 1 LT GRN 1 TAN
12 S127
1 TAN
12
11
S115 1 TAN
12 1 LT GRN
11
C
B
LO
A
LH HEADLIGHT HI
LH COMPOSITE HEADLIGHT ASSEMBLY
1 LT GRN
11
C
B
LO
A
RH HEADLIGHT
RH COMPOSITE HEADLIGHT
HI ASSEMBLY
1 DK BLU/WHT
8
593 1 BLK
151
2 BLK
151
C101 P101
G115
FIGURE 56–27 Typical daytime running light (DRL) circuit. Follow the arrows from the DRL module through both headlights. Notice that the left and right headlights are connected in series, resulting in increased resistance, less current flow, and dimmer than normal lighting. When the normal headlights are turned on, both headlights receive full battery voltage, with the left headlight grounding through the DRL module.
a forward-facing light sensor that is used to detect darkness and signal the rearward-facing sensor to begin to check for excessive glare from headlights behind the vehicle. The rearward-facing sensor sends a voltage to the electrochromic gel in the mirror that is in proportion to the amount of glare detected. The mirror dims in
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CHAPTER 5 6
proportion to the glare and then becomes like a standard rearview mirror when the glare is no longer detected. If automatic dimming mirrors are used on the exterior, the sensors in the interior mirror and electronics are used to control both the interior and exterior mirrors. SEE FIGURE 56–30.
REAR-FACING SENSOR
LIGHTS SWITCH OFF
BATTERY
ON
LIGHTS SWITCH OFF ON
DIMMER SWITCH HIGH
COMMON
LOW
3-LEAD HEADLIGHTS
COMMON
LOW
HIGH
DIMMER SWITCH GROUND
POSITIVE SWITCHING
NEGATIVE SWITCHING
FIGURE 56–28 Most vehicles use positive switching of the high- and low-beam headlights. Notice that both filaments share the same ground connection. Some vehicles use negative switching and place the dimmer switch between the filaments and the ground.
FORWARD-FACING SENSOR
SWITCH
ELECTRICAL CONNECTOR
FIGURE 56–30 An automatic dimming mirror compares the amount of light toward the front of the vehicle to the rear of the vehicle and allies a voltage to cause the gel to darken the mirror.
?
FREQUENTLY ASKED QUESTION
What Is the Troxler Effect? The Troxler effect, also called Troxler fading, is a visual effect where an image remains on the retina of the eye for a short time after the image has been removed. The effect was discovered in 1804 by Igney Paul Vital Troxler (1780–1866), a Swiss physician. Because of the Troxler effect, headlight glare can remain on the retina of the eye and create a blind spot. At night, this fading away of the bright lights from the vehicle in the rear reflected by the rearview mirror can cause a hazard.
FIGURE 56–29 A typical courtesy light doorjamb switch. Newer vehicles use the door switch as an input to the vehicle computer and the computer turns the interior lights on or off. By placing the lights under the control of the computer, the vehicle engineers have the opportunity to delay the lights after the door is closed and to shut them off after a period of time to avoid draining the battery.
DIAGNOSIS AND SERVICE
If a customer concern states that the mirrors do not dim when exposed to bright headlights from the vehicle behind, the cause could be sensors or the mirror itself. Be sure that the mirror is getting electrical power. Most automotive dimming mirrors have a green light to indicate the presence of electrical power. If no voltage is found at the mirror, follow standard troubleshooting procedures to find the cause. If the mirror is getting voltage, start the diagnosis by placing a strip of tape over the forward-facing light sensor. Turn the ignition key on, engine off (KOEO), and observe the operation of the mirror when a flashlight or trouble light is directed onto the mirror. If the mirror reacts and dims, the forward-facing sensor is defective. Most often, the entire
TECH TIP The Weirder the Problem, the More Likely It Is a Poor Ground Connection Bad grounds are often the cause for feedback or lamps operating at full or partial brilliance. At first the problem looks weird because often the switch for the lights that are on dimly is not even turned on. When an electrical device is operating and it lacks a proper ground connection, the current will try to find ground and will often cause other circuits to work. Check all grounds before replacing parts.
mirror assembly has to be replaced if any sensor or mirror faults are found. One typical fault with automatic dimming mirrors is a crack can occur in the mirror assembly, allowing the gel to escape from between the two layers of glass. This gel can drip onto the dash or center console and harm these surfaces. The mirror should be replaced at the first sign of any gel leakage.
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FEEDBACK
Problem
Possible Causes and/or Solutions
One headlight out (low or high beam)
1. Burned out headlight filament (Check the headlight with an ohmmeter. There should be a low-ohm reading between the power-side connection and the ground terminal of the bulb.)
DEFINITION
When current that lacks a good ground goes backward along the power side of the circuit in search of a return path (ground) to the battery, this reverse flow is called feedback, or reverse-bias current flow. Feedback can cause other lights or gauges that should not be working to actually turn on.
FEEDBACK EXAMPLE
A customer complained that when the headlights were on, the left turn signal indicator light on the dash remained on. The cause was found to be a poor ground connection for the left front parking light socket. The front parking light bulb is a dual filament: one filament for the parking light (dim) and one filament for the turn signal operation (bright). A corroded socket did not provide a good enough ground to conduct all current required to light the dim filament of the bulb. The two filaments of the bulb share the same ground connection and are electrically connected. When all the current could not flow through the bulb’s ground in the socket, it caused a feedback or reversed its flow through the other filament, looking for ground. The turn signal filament is electrically connected to the dash indicator light; therefore, the reversed current on its path toward ground could light the turn signal indicator light. Cleaning or replacing the socket usually solves the problem if the ground wire for the socket is making a secure chassis ground connection.
LIGHTING SYSTEM DIAGNOSIS
2. Open circuit (no 12 volts to the bulb) Both high and lowbeam headlights out
1. Burned out bulbs (Check for voltage at the wiring connector to the headlights for a possible open circuit to the headlights or open [defective] dimmer switch.) 2. Open circuit (no 12 volts to the bulb)
All headlights inoperative
1. Burned out filaments in all headlights (Check for excessive charging system voltage.) 2. Defective dimmer switch 3. Defective headlight switch
Slow turn signal operation
1. Defective flasher unit 2. High resistance in sockets or ground wire connections 3. Incorrect bulb numbers
Turn signals operating 1. Burned out bulb on affected side on one side only 2. Poor ground connection or defective socket on affected side 3. Incorrect bulb number on affected side 4. Defective turn signal switch
Diagnosing any faults in the lighting and signaling systems usually includes the following steps. STEP 1
Verify the customer concern.
STEP 2
Perform a visual inspection, checking for collision damage or other possible causes that would affect the operation of the lighting circuit.
STEP 3
Connect a factory or enhanced scan tool with bidirectional control of the computer modules to check for proper operation of the affected lighting circuit.
STEP 4
Follow the diagnostic procedure as found in service information to determine the root cause of the problem.
LIGHTING SYSTEM SYMPTOM GUIDE
Interior light(s) inoperative
1. Burned out bulb(s) 2. Open in the power-side circuit (blown fuse) 3. Open in doorjamb switch(es)
Interior lights on all the time
1. Shorted doorjamb switch
Brake lights inoperative
1. Defective brake switch
2. Shorted control switch
2. Defective turn signal switch 3. Burned out brake light bulbs 4. Open circuit or poor ground connection 5. Blown fuse
Hazard warning lights inoperative
The following list will assist technicians in troubleshooting lighting systems.
1. Defective hazard flasher unit 2. Open in hazard circuit 3. Blown fuse 4. Defective hazard switch
Problem
Possible Causes and/or Solutions
One headlight dim
1. Poor ground connection on body 2. Corroded connector
Hazard warning lights blinking too rapidly
1. Incorrect flasher unit 2. Shorted wiring to front or rear lights 3. Incorrect bulb numbers
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TAILLIGHT BULB REPLACEMENT
1
The driver noticed that the taillight fault indicator (icon) on the dash was on any time the lights were on.
2
A visual inspection at the rear of the vehicle indicated that the right rear taillight bulb did not light. Removing a few screws from the plastic cover revealed the taillight assembly.
3
The bulb socket is removed from the taillight assembly by gently twisting the base of the bulb counterclockwise.
4
The bulb is removed from the socket by gently grasping the bulb and pulling the bulb straight out of the socket. Many bulbs required that you rotate the bulb 90° (1/4 turn) to release the retaining bulbs.
5
The new 7443 replacement bulb is being checked with an ohmmeter to be sure that it is okay before it is installed in the vehicle.
6
The replacement bulb in inserted into the taillight socket and the lights are turned on to verify proper operation before putting the components back together. CONTINUED
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OPTICAL HEADLIGHT AIMING
1
Before checking the vehicle for headlight aim, be sure that all the tires are at the correct inflation pressure, and that the suspension is in good working condition.
2
The headlight aim equipment will have to be adjusted for the slope of the floor in the service bay. Start the process by turning on the laser light generator on the side of the aimer body.
3
Place a yardstick or measuring tape vertically in front of the center of the front wheel, noting the height of the laser beam.
4
Move the yardstick to the center of the rear wheel and measure the height of the laser beam at this point. The height at the front and rear wheels should be the same.
5
If the laser beam height measurements are not the same, the floor slope of the aiming equipment must be adjusted. Turn the floor slope knob until the measurements are equal.
6
Place the aimer in front of the headlight to be checked, at a distance of 10 to 14 inches (25 to 35 cm). Use the aiming pointer to adjust the height of the aimer to the middle of the headlight.
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STEP BY STEP
7
Align the aimer horizontally, using the pointer to place the aimer at the center of the headlight.
8
9
Turn on the vehicle headlights, being sure to select the correct beam position for the headlight to be aimed.
10
View the light beam through the aimer window. The position of the light pattern will be different for high and low beams.
12
If adjustment is required, move the headlight adjusting screws using a special tool or a 1/4-in. drive ratchet/socket combination. Watch the light beam through the aimer window to verify the adjustment.
11
If the first headlight is aimed adequately, move the aimer to the headlight on the opposite side of the vehicle. Follow the previous steps to position the aimer accurately.
Lateral alignment (aligning the body of the aimer with the body of the vehicle) is done by looking through the upper visor. The line in the upper visor is aligned with symmetrical points on the vehicle body.
CONTINUED
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REVIEW QUESTIONS 1. Why should the exact same trade number of bulb be used as a replacement? 2. Why is it important to avoid touching a halogen bulb with your fingers?
3. How do you diagnose a turn signal operating problem? 4. How do you aim headlights on a vehicle equipped with aerodynamic-style headlights?
CHAPTER QUIZ 1. Technician A says that the bulb trade number is the same for all bulbs of the same size. Technician B says that a dual-filament bulb has different candlepower ratings for each filament. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
7. A technician replaced a 1157NA with a 1157A bulb. Which is the most likely result? a. The bulb is brighter because the 1157A candlepower is higher. b. The amber color of the bulb is a different shade. c. The bulb is dimmer because the 1157A candlepower is lower. d. Both b and c
2. Two technicians are discussing flasher units. Technician A says that only a DOT-approved flasher unit should be used for turn signals. Technician B says that a parallel (variable-load) flasher will function for turn signal usage, although it will not warn the driver if a bulb burns out. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
8. A customer complained that every time he turned on his vehicle’s lights, the left-side turn signal indicator light on the dash remained on. The most likely cause is a ______________. a. Poor ground to the parking light (or taillight) bulb on the left side b. Poor ground to the parking light (or taillight) bulb on the right side, causing current to flow to the left-side lights c. Defective (open) parking light (or taillight) bulb on the left side d. Both a and c
3. Interior overhead lights (dome lights) are operated by doorjamb switches that ______________. a. Complete the power side of the circuit b. Complete the ground side of the circuit c. Move the bulb(s) into contact with the power and ground d. Either a or b depending on application 4. Electrical feedback is usually a result of ______________. a. Too high a voltage in a circuit b. Too much current (in amperes) in a circuit c. Lack of a proper ground d. Both a and b 5. According to Chart 56–1, which bulb is brightest? a. 194 c. 194NA b. 168 d. 1157 6. If a 1157 bulb were to be installed in a left front parking light socket instead of a 2057 bulb, what would be the most likely result? a. The left turn signal would flash faster. b. The left turn signal would flash slower. c. The left parking light would be slightly brighter. d. The left parking light would be slightly dimmer.
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9. A defective taillight or front park light bulb could cause the ______________. a. Turn signal indicator on the dash to light when the lights are turned on b. Dash lights to come on when the brake lights are on c. Lights-on warning chime to sound if the brake pedal is depressed d. All of the above 10. A defective brake switch could prevent proper operation of the ______________. a. Cruise control c. Shift interlock b. ABS brakes d. All of the above
chapter
DRIVER INFORMATION AND NAVIGATION SYSTEMS
57
OBJECTIVES: After studying Chapter 57, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “F” (Gauges, Warning Devices, and Driver Information System Diagnosis and Repair). • Be able to identify the meaning of dash warning symbols. • Discuss how a fuel gauge works. • Explain how to use a service manual to troubleshoot a malfunctioning dash instrument. • Describe how a navigation system works. • List the various types of dash instrument displays. KEY TERMS: Backup camera 640 • CFL 634 • Combination valve 628 • CRT 634 • EEPROM 637 • GPS 637 • HUD 630 • IP 629 • LCD 633 • LDWS 641 • LED 633 • NVRAM 637 • Phosphor 633 • PM generator 635 • Pressure differential switch 628 • RPA 641 • Stepper motor 629 • VTF 633 • WOW display 634
OR
DASH WARNING SYMBOLS
HOT
FIGURE 57–1 Engine coolant temperature is too high.
PURPOSE AND FUNCTION
All vehicles are equipped with warning lights that are often confusing to drivers. Because many vehicles are sold throughout the world, symbols instead of words are being used as warning lights. The dash warning lights are often called telltale lights as they are used to notify the driver of a situation or fault.
BULB TEST When the ignition is first turned on, all of the warning lights come on as part of a self-test and to help the driver or technician spot any warning light that may be burned out. Technicians or drivers who are familiar with what lights should light may be able to determine if one or more warning lights are not on when the ignition is first turned on. Most factory scan tools can be used to command all of the warning lights on to help determine if one is not working. ENGINE FAULT WARNING
OR
FIGURE 57–2 Engine oil pressure too low.
FIGURE 57–3 Water detected in fuel. Notice to drain the water from the fuel filter assembly on a vehicle equipped with a diesel engine. 3. Check the oil level.
Engine fault warning lights include
4. Do not drive the vehicle with the engine oil light on or severe engine damage can occur.
the following:
Engine coolant temperature. This warning lamp should come on when the ignition is first turned on as a bulb check and if the coolant temperature reaches 248°F to 258°F (120°C to 126°C), depending on the make and model of the vehicle. SEE FIGURE 57–1.
SEE FIGURE 57–2.
If the engine coolant temperature warning lamp comes on while driving, perform the following in an attempt to reduce the temperature.
Water in diesel fuel warning. This warning lamp will light when the ignition is first turned on as a bulb check and if water is detected in the diesel fuel. This lamp is only used or operational in vehicles equipped with a diesel engine. If the water in diesel fuel warning lamp comes on, do the following:
1. Turn off the air conditioning.
1. Remove the water using the built-in drain, usually part of the fuel filter.
2. Turn on the heater.
2. Check service information for the exact procedure to follow.
3. If the hot light remains on, drive to a safe location and shut off the engine and allow it to cool to help avoid serious engine damage.
OIL
SEE FIGURE 57–3.
Maintenance required warning. The maintenance required lamp comes on when the ignition is first turned on as a bulb check and if the vehicle requires service. The service required could include:
Engine oil pressure. This warning lamp should light when the ignition is first turned on as a bulb check; or if the engine oil pressure light comes on when driving, perform the following:
1. Oil and oil filter change
1. Pull off the road as soon as possible.
2. Tire rotation
2. Shut off the engine.
3. Inspection
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MAINT REQD
FIGURE 57–4 Maintenance required. This usually means that the engine oil is scheduled to be changed or other routine service items replaced or checked.
OR
OR CHECK
SERVICE ENGINE SOON
FIGURE 57–5 Malfunction indicator lamp (MIL), also called a check engine light. The light means the engine control computer has detected a fault.
FIGURE 57–7 Fasten safety belt warning light.
FIGURE 57–8 Fault detected in the supplemental restraint (airbag) system.
OR
BRAKE
FIGURE 57–9 Fault detected in base brake system. FIGURE 57–6 Charging system fault detected. Check service information for the exact service required. SEE FIGURE 57–4.
Malfunction indicator lamp (MIL), also called a check engine or service engine soon (SES) light. This warning lamp comes on when the ignition is first turned on as a bulb test and then only if a fault in the powertrain control module (PCM) has been detected. If the MIL comes on when driving, it is not necessary to stop the vehicle, but the cause for why the warning lamp came on should be determined as soon as possible to avoid harming the engine or engine control systems. The MIL could come on if any of the following has been detected.
FIGURE 57–10 Brake light bulb failure detected.
FIGURE 57–11 Exterior light bulb failure detected. side or passenger’s side safety belt is not fastened. It is also used to indicate a fault in the safety belt circuit. Check service information for the exact procedure to follow if the safety belt warning light remains on even when the belts are fastened. SEE FIGURE 57–7.
1. A sensor or actuator is electrically open or shorted. 2. A sensor is out of range for expected values. 3. An emission control system failure occurs, such as a loose gas cap.
If the MIL is on, a diagnostic trouble code has been set. Use a scan tool to retrieve the code(s) and follow service information for the exact procedure to follow. SEE FIGURE 57–5.
ELECTRICAL SYSTEM–RELATED WARNING LIGHTS
Charging system fault. This warning lamp will come on when the ignition is first turned on as a bulb check and if a fault in the charging system has been detected. The lamp could include a fault with any of the following:
NOTE: The passenger side airbag light may indicate that it is on or off, depending if there is a passenger or an object heavy enough to trigger the seat sensor.
1. Battery state of charge (SOC), electrical connections, or the battery itself 2. Alternator or related wiring If the charge system warning lamp comes on, continue to drive until it is safe to pull over. The vehicle can usually be driven for several miles using battery power alone.
2. A pressure switch located in the pressure differential switch, which detects a difference in pressure between the front and rear or diagonal brake systems
Check the following by visible inspection.
3. The parking brake could be applied. SEE FIGURE 57–9.
1. Alternator drive belt
If the red brake warning light comes on, do not drive the vehicle until the cause is determined and corrected.
2. Loose or corroded electrical connections at the battery 3. Loose or corroded wiring to the alternator
Brake light bulb failure. Some vehicles are able to detect if a brake light is burned out. The warning lamp will warn the driver when a situation like this occurs. SEE FIGURE 57–10.
Exterior light bulb failure. Many vehicles use the body control module (BCM) to monitor current flow through all of the exterior lights and therefore can detect if a bulb is not working. SEE FIGURE 57–11.
4. Defective alternator Safety-related warn-
ing lamps include the following:
Safety belt warning lamp. The safety belt warning lamp will light and sound an alarm to notify the driver if the driver’s
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C H A P T ER 57
Red brake fault warning light. All vehicles are equipped with a red brake warning (RBW) lamp that lights if a fault in the base (hydraulic) brake system is detected. Three types of sensors are used to light this warning light. 1. A brake fluid level sensor located in the master cylinder brake fluid reservoir
SEE FIGURE 57–6.
SAFETY-RELATED WARNING LAMPS
Airbag warning lamp. The airbag warning lamp comes on and flashes when the ignition is first turned on as part of a self-test of the system. If the airbag warning lamp remains on after the self-test, then the airbag controller has detected a fault. Check service information for the exact procedure to follow if the airbag warning lamp is on. SEE FIGURE 57–8.
OR FIGURE 57–12 Worn brake pads or linings detected.
ABS
OR
ABS
OR
FIGURE 57–16 Windshield washer fluid low.
ABS
OR
LOW FUEL
FIGURE 57–13 Fault detected in antilock brake system. FIGURE 57–17 Low fuel level.
OR
OR
FIGURE 57–14 Low tire pressure detected.
OR
DOOR OPEN
FIGURE 57–18 Headlights on.
OR
FIGURE 57–15 Door open or ajar. TECH TIP Check the Spare Some vehicles that are equipped with a full-size spare tire also have a sensor in the spare. If the warning lamp is on and all four tires are properly inflated, check the spare.
Worn brake pads. Some vehicles are equipped with sensors built into the disc brake pads that are used to trigger a dash warning light. The warning light often comes on when the ignition is first turned on as a bulb check and then goes out. If the brake pad warning lamp is on, check service information for the exact service procedure to follow. SEE FIGURE 57–12. Antilock brake system (ABS) fault. The amber antilock brake system warning light comes on if the ABS controller detects a fault in the antilock braking system. Examples of what could trigger the warning light include:
FIGURE 57–19 Low traction detected. Traction control system is functioning to restore traction (usually flashes when actively working to restore traction).
VSC FIGURE 57–20 Vehicle stability control system either off or working if flashing.
TRAC OFF FIGURE 57–21 Traction control system has been turned off.
Low fuel warning. A low fuel indicator light is used to warn the driver that the fuel level is low. In most vehicles, the light comes on when there is between 1 and 3 gallons (3.8 and 11 liters) of fuel remaining. SEE FIGURE 57–17.
Headlights on light. This dash indicator lights whenever the headlights are on. SEE FIGURE 57–18.
1. Defective wheel speed sensor 2. Low brake fluid level in the hydraulic control unit assembly
NOTE: This light may or may not indicate that the headlights are on if the headlight switch is set to the automatic position.
3. Electrical fault detected anywhere in the system
SEE FIGURE 57–13. If the amber ABS warning lamp is on, it is safe to drive the vehicle, but the antilock portion may not function.
Low tire pressure warning. A tire pressure monitoring system (TPMS) warns if the inflation pressure of a tire has decreased by 25% (about 8 psi). If the warning lamp or message of a low tire is displayed, check the tire pressures before driving. If the inflation pressure is low, repair or replace the tire. SEE FIGURE 57–14.
Low traction detected. On a vehicle equipped with a traction control system (TCS), a dash indicator light is flashed whenever the system is working to restore traction. If the low traction warning light is flashing, reduce the rate of acceleration to help the system restore traction of the drive wheels with the road surface. SEE FIGURE 57–19.
Electronic stability control. If a vehicle is equipped with electronic stability control (ESC), also called vehicle stability control (VSC), the dash indicator lamp will flash if the system is trying to restore vehicle stability. SEE FIGURE 57–20.
Traction off. If the traction control system (TCS) is turned off by the driver, an indicator lamp lights to help remind the driver that this system has been turned off and will not be able to restore traction when lost. The system reverts to on, when the ignition is turned off, and then back on as the traction off button is depressed. SEE FIGURE 57–21.
DRIVER INFORMATION SYSTEM
Door open or ajar warning light. If a door is open or ajar, a warning light is used to notify the driver. Check and close all doors and tailgates before driving. SEE FIGURE 57–15.
Windshield washer fluid low. A sensor in the windshield washer fluid reservoir is used to turn on the low washer fluid warning lamp. SEE FIGURE 57–16.
TRAC
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CRUISE FIGURE 57–22 Indicates that the cruise control is on and able to maintain vehicle speed if set. Some vehicles use a symbol that looks like a small speedometer to indicate that the cruise control is on. RESISTANCE UNIT
SLIDING CONTACTS
TO GAUGE
ARM
DIAPHRAGM
OIL PRESSURE
SENDING UNIT (ATTACHED TO ENGINE)
FIGURE 57–23 A typical oil pressure sending unit provides a varying amount of resistance as engine oil pressure changes. The output from the sensor is a variable voltage.
Cruise indicator lamp. Most vehicles are equipped with a switch that turns on the cruise control. The cruise (speed) control system does not work unless it has been turned on to help prevent accidental engagement. When the cruise control has been turned on, the cruise indicator light is on. SEE FIGURE 57–22.
OIL PRESSURE WARNING DEVICES OPERATION The oil pressure lamp operates through use of an oil pressure sensor unit, which is screwed into the engine block, and grounds the electrical circuit and lights the dash warning lamp in the event of low oil pressure, that is, 3 to 7 psi (20 to 50 kilopascals [kPa]). Normal oil pressure is generally between 10 and 60 psi (70 and 400 kPa). Some vehicles are equipped with a variable voltage oil pressure sensors rather than a simple pressure switch. SEE FIGURE 57–23. OIL PRESSURE LAMP DIAGNOSIS To test the operation of the oil pressure warning circuit, unplug the wire from the oil pressure sending unit, usually located near the oil filter, with the ignition switch on. With the wire disconnected from the sending unit, the warning lamp should be off. If the wire is touched to a ground, the warning lamp should be on. If there is any doubt of the operation of the oil pressure warning lamp, always check the actual engine oil pressure using a gauge that can be screwed into the opening that is left after unscrewing the oil pressure sending unit. For removing the sending unit, special sockets are available at most auto parts stores, or a 1 in. or 1 1/16 in. 6-point socket may be used for most units.
TEMPERATURE LAMP DIAGNOSIS The “hot” lamp, or engine coolant overheat warning lamp, warns the driver whenever the engine coolant temperature is between 248°F and 258°F (120°C and 126°C). This temperature is slightly below the
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C H A P T ER 57
FIGURE 57–24 A temperature gauge showing normal operating temperature between 180°F and 215°F, depending on the specific vehicle and engine.
REAL WORLD FIX The Low Oil Pressure Story After replacing valve cover gaskets on a Chevrolet V-8, the technician discovered that the oil pressure warning lamp was on. After checking the oil level and finding everything else okay, the technician discovered a wire pinched under the valve cover. The wire went to the oil pressure sending unit. The edge of the valve cover had cut through the insulation and caused the current from the oil lamp to go to ground through the engine. Normally the oil lamp comes on when the sending unit grounds the wire from the lamp. The technician freed the pinched wire and covered the cut with silicone sealant to prevent corrosion damage.
boiling point of the coolant in a properly operating cooling system. The temperature sensor on older models was separate from the sensor used by the engine computer. However, most vehicles now use the engine coolant temperature (ECT) sensor for engine temperature gauge operation. To test this sensor, use a scan tool to verify proper engine temperature and follow the vehicle manufacturer’s recommended testing procedures. SEE FIGURE 57–24.
BRAKE WARNING LAMP All vehicles sold in the United States after 1967 must be equipped with a dual braking system and a dash-mounted warning lamp to signal the driver of a failure in one part of the hydraulic brake system. The switch that operates the warning lamp is called a pressure differential switch. This switch is usually the center portion of a multipurpose brake part called a combination valve. If there is unequal hydraulic pressure in the braking system, the switch usually provides a ground path for the brake warning lamp, and the lamp comes on. SEE FIGURE 57–25. Unfortunately, the dash warning lamp is often the same lamp as that used to warn the driver that the parking brake is on. The warning lamp is usually operated by using the parking brake lever
LEAD TO BRAKE WARNING LIGHT BRAKE WARNING LIGHT SWITCH
sensors are the same regardless of the type of display used. The resistance of the sensor varies with what is being measured. SEE FIGURE 57–27 for typical electromagnetic fuel gauge operation.
NETWORK COMMUNICATION DESCRIPTION
PRESSURE DIFFERENTIAL SWITCH (USUALLY A PART OF THE COMBINATION VALVE)
FIGURE 57–25 Typical brake warning light switch located on or near the master brake cylinder.
BRAKE FLUID LEVEL SENSOR
Many instrument panels are operated by electronic control units that communicate with the engine control computer for engine data such as revolutions per minute (rpm) and engine temperature. These electronic instrument panels (IPs) use the voltage changes from variable-resistance sensors, such as that of the fuel gauge, to determine fuel level. Therefore, even though the sensor in the fuel tank is the same, the display itself may be computer controlled. The data is transmitted to the instrument cluster as well as to the powertrain control module through serial data lines. Because all sensor inputs are interconnected, the technician should always follow the factory recommended diagnostic procedures. SEE FIGURE 57–28.
STEPPER MOTOR ANALOG GAUGES DESCRIPTION
Most analog dash displays use a stepper motor to move the needle. A stepper motor is a type of electric motor that is designed to rotate in small steps based on the signal from a computer. This type of gauge is very accurate.
OPERATION FIGURE 57–26 The red brake warning lamp can be turned on if the brake fluid level is low. or brake hydraulic pressure switch to complete the ground for the warning lamp circuit. If the warning lamp is on, first check if the parking brake is fully released. If the parking brake is fully released, the problem could be a defective parking brake switch or a hydraulic brake problem. To test for which system is causing the lamp to remain on, simply unplug the wire from the valve or switch. If the wire on the pressure differential switch is disconnected and the warning lamp remains on, then the problem is due to a defective or misadjusted parking brake switch. If, however, the warning lamp goes out when the wire is removed from the brake switch, then the problem is due to a hydraulic brake fault that caused the pressure differential switch to complete the warning lamp circuit. The red brake warning lamp also can be turned on if the brake fluid is low. SEE FIGURE 57–26 for an example of a brake fluid level sensor.
ANALOG DASH INSTRUMENTS An analog display uses a needle to show the value, whereas a digital display uses numbers. Analog electromagnetic dash instruments use small electromagnetic coils that are connected to a sending unit for such things as fuel level, water temperature, and oil pressure. The
A digital output is used to control stepper motors. Stepper motors are direct current motors that move in fixed steps or increments from de-energized (no voltage) to fully energized (full voltage). A stepper motor often has as many as 120 steps of motion. When using a stepper motor that is controlled by the PCM, it is very easy for the PCM to keep track of the stepper motor’s position. By counting the number of steps that have been sent to the stepper motor, the PCM can determine its relative position. While the PCM does not actually receive a feedback signal from the stepper motor, it knows how many steps forward or backward the motor should have moved. A typical stepper motor uses a permanent magnet and two electromagnets. Each of the two electromagnetic windings is controlled by the computer. The computer pulses the windings and changes the polarity of the windings to cause the armature of the stepper motor to rotate 90 degrees at a time. Each 90-degree pulse is recorded by the computer as a “count” or “step,” which explains the name given to this type of motor. SEE FIGURE 57–29. NOTE: Many electronic gauge clusters are checked at key on where the dash display needles will be commanded to 1/4, 1/2, 3/4, and full positions before returning to their normal readings. This self-test allows the service technician to check the operation of each individual gauge, even though replacing the entire instrument panel cluster is usually necessary to repair an inoperative gauge.
DIAGNOSIS The dash electronic circuits are often too complex to show on a wiring diagram. Instead, all related electronic circuits are simply indicated as a solid box with “electronic module” printed
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B+ 12 V
E
F GAUGE NEEDLE
EMPTY
FULL
SENSOR
ELECTRICAL WIRING INSIDE DASH UNIT
GAUGE GROUNDED TO CHASSIS
GROUND OFF IGNITION
TANK UNIT (SENDER)
ON IGNITION SWITCH
DASH UNIT GAUGE (REAR VIEW)
BODY WIRING FRONT BODY CONNECTOR
TANK UNIT GROUNDED TO CHASSIS
REAR BODY CONNECTOR
BATTERY GROUNDED TO CHASSIS TYPICAL GAS GAUGE SYSTEM SCHEMATIC
FIGURE 57–27 Electromagnetic fuel gauge wiring. If the sensor wire is unplugged and grounded, the needle should point to “E” (empty). If the sensor wire is unplugged and held away from ground, the needle should point to “F” (full). COOLANT TEMPERATURE
TACHOMETER
4 3 2 1 0
5 6
SPEEDOMETER
80
7 8
100 120 140
60 160 40 20
+
180
x1000rpm
on the diagram. Even if all the electronic circuits were shown on the wiring diagram, it would require the skill of an electronics engineer to determine exactly how the circuit was designed to work. SEE FIGURE 57–30. Note that the grounding for the “check oil” dash indicator lamp is accomplished through an electronic buffer. The exact conditions, such as amount of time since the ignition was shut off, are unknown to the technician. To correctly diagnose problems with this type of circuit, technicians must read, understand, and follow the written diagnostic procedures specified by the vehicle manufacturer.
CLASS 2
PIN 2
DLC
FIGURE 57–28 A typical instrument display uses data from the sensors over serial data lines to the individual gauges.
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HEAD-UP DISPLAY The head-up display (HUD) is a supplemental display that projects the vehicle speed and sometimes other data, such as turn signal information, onto the windshield. The projected image looks as if it
S
N
N
S
STEP 1
N
S
STEP 2
S
N
S
N
N
S
FIGURE 57–29 Most stepper motors use four wires which are pulsed by the computer to rotate the armature in steps. HOT IN RUN, BULB TEST OR START FUSE BLOCK
GAUGES FUSE 10 AMP
.5 ORN/BLK
INSTRUMENT CLUSTER PRINTED CIRCUIT
1733
M
CHECK GAUGES INDICATOR (AMBER)
SENDER INPUT SOLID STATE
CHECK GAUGES
INDICATORS, GAUGES CHECK GAUGES BUFFER
CHECK OIL INDICATOR (AMBER)
LOW OIL BUFFER
CHECK OIL
T
L
C100
.8 BRN/WHT
1173
B
FLOAT MAGNET A
.8 BLK
OIL LEVEL SWITCH (OPEN WITH LOW OIL LEVEL)
150
G109
FIGURE 57–30 The ground for the “check oil” indicator lamp is controlled by the electronic low-oil buffer. Even though this buffer is connected to an oil level sensor, the buffer also takes into consideration the amount of time the engine has been stopped and the temperature of the engine. The only way to properly diagnose a problem with this circuit is to use the procedures specified by the vehicle manufacturer. Besides, only the engineer who designed the circuit knows for sure how it is supposed to work.
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WINDSHIELD DISPLAY
30 MPH FLAT MIRROR
CONCAVE MIRROR (ADJUSTABLE FOR POSITION)
PROJECTOR
FIGURE 57–33 A typical head-up display (HUD) unit.
FIGURE 57–31 A typical head-up display showing zero miles per hour, which is actually projected on the windshield from the head-up display in the dash.
FIGURE 57–34 A night vision camera behind the grille of a Cadillac.
FIGURE 57–32 The dash-mounted control for the head-up display on this Cadillac allows the driver to move the image up and down on the windshield for best viewing. is some distance ahead, making it easy for the driver to see without having to refocus on a closer dash display. SEE FIGURES 57–31 AND 57–32. The head-up display can also have the brightness controlled on most vehicles that use this type of display. The HUD unit is installed in the instrument panel (IP) and uses a mirror to project vehicle information onto the inside surface of the windshield. SEE FIGURE 57–33. Follow the vehicle manufacturer’s recommended diagnostic and testing procedures if any faults are found with the head-up display.
NIGHT VISION PARTS AND OPERATION
Night vision systems use a camera that is capable of observing objects in the dark to assist the driver while driving at night. The primary night viewing illumination devices
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are the headlights. The night vision option uses a head-up display (HUD) to improve the vision of the driver beyond the scope of the headlights. Using a HUD display allows the driver to keep eyes on the road and hands on the wheel for maximum safety. Besides the head-up display, the night vision camera uses a special thermal imaging or infrared technology. The camera is mounted behind the grille in the front of the vehicle. SEE FIGURE 57–34. The camera creates pictures based on the heat energy emitted by objects rather than from light reflected on an object as in a normal optical camera. The image looks like a black and white photo negative when hot objects (higher thermal energy) appear light or white, and cool objects appear dark or black. Other parts of the night vision system include:
On/off and dimming switch. This allows the driver to adjust the brightness of the display and to turn it on or off as needed.
Up/down switch. The night vision HUD system has an electric tilt adjust motor that allows the driver to adjust the image up or down on the windshield within a certain image.
CAUTION: Becoming accustomed to night vision can be difficult and may take several nights to get used to looking at the head-up display.
DIAGNOSIS AND SERVICE The first step when diagnosing a fault with the night vision system is to verify the concern. Check the owner manual or service information for proper operation. For
example, the Cadillac night vision system requires the following actions to function.
CATHODE
1. The ignition has to be in the on (run) position.
INDIVIDUAL LED
2. The Twilight Sentinel photo cell must indicate that it is dark. 3. The headlights must be on.
– CATHODE
4. The switch for the night vision system must be on and the brightness adjusted so the image is properly displayed.
LED SYMBOL
+ ANODE
ANODE
(a)
The night vision system uses a camera in the front of the vehicle that is protected from road debris by a grille. However, small stones or other debris can get past the grille and damage the lens of the camera. If the camera is damaged, it must be replaced as an assembly because no separate parts are available. Always follow the vehicle manufacturer’s recommended testing and servicing procedures.
DIGITAL ELECTRONIC DISPLAY OPERATION (c)
TYPES
Mechanical or electromechanical dash instruments use cables, mechanical transducers, and sensors to operate a particular dash instrument.
Digital dash instruments use various electric and electronic sensors that activate segments or sections of an electronic display. Most electronic dash clusters use a computer chip and various electronic circuits to operate and control the internal power supply, sensor voltages, and display voltages.
Electronic dash display systems may use one or more of several types of displays: light-emitting diode (LED), liquid crystal display (LCD), vacuum tube fluorescent (VTF), and cathode ray tube (CRT).
B+ (b)
FIGURE 57–35 (a) Symbol and line drawing of a typical lightemitting diode (LED). (b) Grouped in seven segments, this array is called a seven-segment LED display with a common anode (positive connection). The dash computer toggles the cathode (negative) side of each individual segment to display numbers and letters. (c) When all segments are turned on, the number 8 is displayed.
polarized to let the light through, which then show numbers or letters. Color filters can be placed in front of the display to change the color of certain segments of the display, such as the maximum engine speed on a digital tachometer.
LED DIGITAL DISPLAYS
All diodes emit some form of energy during operation; the light-emitting diode (LED) is a semiconductor that is constructed to release energy in the form of light. Many colors of LEDs can be constructed, but the most popular are red, green, and yellow. Red is difficult to see in direct sunlight; therefore, if an LED is used, most vehicle manufacturers use yellow. Light-emitting diodes can be arranged in a group of seven, which then can be used to display both numbers and letters. SEE FIGURE 57–35. An LED display requires more electrical power than other types of electronic displays. A typical LED display requires 30 mA for each segment; therefore, each number or letter displayed could require 210 mA (0.210 A).
LIQUID CRYSTAL DISPLAYS Liquid crystal displays (LCDs) can be arranged into a variety of forms, letters, numbers, and bar graph displays.
LCD construction consists of a special fluid sandwiched between two sheets of polarized glass. The special fluid between the glass plates will permit light to pass if a small voltage is applied to the fluid through a conductive film laminated to the glass plates. The light from a very bright halogen bulb behind the LCD shines through those segments of the LCD that have been
CAUTION: Be careful, when cleaning an LCD, not to push on the glass plate covering the special fluid. If excessive pressure is exerted on the glass, the display may be permanently distorted. If the glass breaks, the fluid will escape and could damage other components in the vehicle as a result of its strong alkaline nature. Use only a soft, damp cloth to clean these displays.
The major disadvantage of an LCD digital dash is that the numbers or letters are slow to react or change at low temperatures. SEE FIGURE 57–36.
VACUUM TUBE FLUORESCENT DISPLAYS
The vacuum tube fluorescent (VTF) display is a popular automotive and household appliance display because it is very bright and can easily be viewed in strong sunlight. The usual VTF display is green, but white is often used for home appliances.
The VTF display generates its bright light in a manner similar to that of a TV screen, where a chemical-coated lightemitting element called a phosphor is hit with high-speed electrons.
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(a)
FIGURE 57–36 A typical navigation system. This Honda/Acura system uses some of the climate control functions as well as the trip information on the display. This particular unit uses a DVD unit in the trunk along with a global positioning satellite (GPS) to display a map and your exact location for the entire country. (b)
VTF displays are very bright and must be dimmed by use of dense filters or by controlling the voltage applied to the display. A typical VTF dash is dimmed to 75% brightness whenever the parking lights or headlights are turned on. Some displays use a photocell to monitor and adjust the intensity of the display during daylight viewing. Most VTF displays are green for best viewing under most lighting conditions.
CATHODE RAY TUBE
A cathode ray tube (CRT) dash display, which is similar to a television tube or LCD display, permits the display of hundreds of controls and diagnostic messages in one convenient location. Using the touch-sensitive cathode ray tube, the driver or technician can select from many different displays, including those of radio, climate, trip, and dash instrument information. The driver can readily access all of these functions. Further diagnostic information can be displayed on the CRT if the proper combination of air-conditioning controls is touched. The diagnostic procedures for these displays involve pushing two or more buttons at the same time to access the diagnostic menu. Always follow the factory service manual recommendations.
COLD CATHODE FLUORESCENT DISPLAYS
Cold cathode fluorescent lighting (CFL) models are used by many vehicle manufacturers for backlighting. Current consumption ranges from 3 to 5 mA (0.003 to 0.005 A) with an average life of 40,000 hours. CFL is replacing conventional incandescent light bulbs.
ELECTRONIC ANALOG DISPLAYS
Most analog dash displays since the early 1990s are electronically or computer controlled. The sensors may be the same, but the sensor information is sent to the body or vehicle computer through a data BUS, and then the computer controls current through small electromagnets that move the needle of the gauge. SEE FIGURE 57–37. A scan tool often is needed to diagnosis the operation of a computer-controlled analog dash instrument display.
WOW DISPLAY When a vehicle equipped with a digital dash is started, all segments of the electronic display are turned on at full brilliance for 1 or 2 seconds. This is commonly called the WOW display, and is used to show off the brilliance of the display. If numbers are part of the display, the number 8 is shown, because this number
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(c) FIGURE 57–37 (a) View of the vehicle dash with the instrument cluster removed. Sometimes the dash instruments can be serviced by removing the padded dash cover (crash pad) to gain access to the rear of the dash. (b) The front view of the electronic analog dash display. (c) The rear view of the dash display showing that there are a few bulbs that can be serviced, but otherwise the unit is serviced as an assembly. TECH TIP The Bulb Test Many ignition switches have six positions. Notice the bulb test position (between “on” and “start”). When the ignition is turned to “on” (run), some dash warning lamps are illuminated. When the bulb test position is reached, additional dash warning lamps often are lighted. Technicians use this ignition switch position to check the operation of fuses that protect various circuits. Dash warning lamps are not all powered by the same fuses. If an electrical component or circuit does not work, the power side (fuse) can be quickly checked by observing the operation of the dash lamps that have a common fuse with the problem circuit. Consult a wiring diagram for fuse information on the exact circuit being tested. SEE FIGURES 57–38 AND 57–39.
uses all segments of a number display. Technicians can also use the WOW display to determine if all segments of the electronic display are functioning correctly.
VEHICLE SPEED (VS) SENSOR
LOCK ACCESSORY
UNLOCK ON (RUN)
BULB TEST
START
FIGURE 57–38 Typical ignition switch positions. Notice the bulb check position between “on” (run) and “start.” These inputs are often just voltage signal to the body control module and can be checked using a scan tool. FIGURE 57–40 A vehicle speed sensor located in the extension housing of the transmission. Some vehicles use the wheel speed sensors for vehicle speed information.
TECH TIP The Soldering Gun Trick
FIGURE 57–39 Many newer vehicles place the ignition switch on the dash and incorporate antitheft controls. Note the location of the accessory position. REAL WORLD FIX The Speedometer Works as if It Is a Tachometer The owner of a Lincoln Town Car complained that all of a sudden the speedometer needle went up and down with engine speed rather than vehicle speed. In fact, the speedometer needle went up and down with engine speed even though the gear selector was in “park” and the vehicle was not moving. After hours of troubleshooting, the service technician went back and started checking the basics and discovered that the alternator had a bad diode. The technician measured over 1 volt AC and over 10 amperes AC ripple current using a clamp-on AC/DC ammeter. Replacing the alternator restored the proper operation of the speedometer.
ELECTRONIC SPEEDOMETERS OPERATION Electronic dash displays ordinarily use an electric vehicle speed sensor driven by a small gear on the output shaft of the transmission. These speed sensors contain a permanent magnet and generate a voltage in proportion to the vehicle speed. These speed sensors are commonly called permanent magnet (PM) generators. SEE FIGURE 57–40.
Diagnosing problems with digital or electronic dash instruments can be difficult. Replacement parts generally are expensive and usually not returnable if installed in the vehicle. A popular trick that helps isolate the problem is to use a soldering gun near the PM generator. A PM generator contains a coil of wire. As the magnet inside revolves, a voltage is produced. It is the frequency of this voltage that the dash (or engine) computer uses to calculate vehicle speed. A soldering gun plugged into 110 volts AC will provide a strong varying magnetic field around the soldering gun. This magnetic field is constantly changing at the rate of 60 cycles per second. This frequency of the magnetic field induces a voltage in the windings of the PM generator. This induced voltage at 60 hertz (Hz) is converted by the computer circuits to a miles per hour (mph) reading on the dash. To test the electronic speedometer, turn the ignition to “on” (engine off) and hold a soldering gun near the PM generator. CAUTION: The soldering gun tip can get hot, so hold it away from wiring or other components that may be damaged by the hot tip. If the PM generator, wiring, computer, and dash are okay, the speedometer should register a speed, usually 54 mph (87 km/h). If the speedometer does not work when the vehicle is driven, the problem is in the PM generator drive. If the speedometer does not register a speed when the soldering gun is used, the problem could be caused by the following: 1. Defective PM generator (check the windings with an ohmmeter) 2. Defective (open or shorted) wiring from the PM generator to the computer 3. Defective computer or dash circuit
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REAL WORLD FIX The Toyota Truck Story The owner of a Toyota truck complained that several electrical problems plagued the truck, including the following: 1. The cruise (speed) control would kick out intermittently. 2. The red brake warning lamp would come on, especially during cold weather. The owner had replaced the parking brake switch, thinking that was the cause of the red brake warning lamp coming on. An experienced technician checked the wiring diagram in service information. Checking the warning lamp circuit, the technician noticed that the same wire went to the brake fluid level sensor. The brake fluid was at the minimum level. Filling the master cylinder to the maximum level with clean brake fluid solved both problems. The electronics of the cruise control stopped operation when the red brake warning lamp was on as a safety measure.
(a)
REAL WORLD FIX Look for Previous Repairs A technician was asked to fix the speedometer on a Pontiac Grand Am that showed approximately double the actual speed. Previous repairs had included a new vehicle speed (VS) sensor and computer. Nothing made any difference. The customer stated that the problem happened all of a sudden. After hours of troubleshooting, the customer just happened to mention that the automatic transaxle had been repaired shortly before the speedometer problem. The root cause of the problem was discovered when the technician learned that a final drive assembly from a 4T60-E transaxle had been installed on the 3T-40 transaxle. The 4T60-E final drive assembly has 13 reluctor teeth whereas the 3T-40 has 7 teeth. This difference in the number of teeth caused the speedometer to read almost double the actual vehicle speed. After the correct part was installed, the speedometer worked correctly. The technician now always asks if there has been any recent work performed in the vehicle prior to any diagnosis.
The output of a PM generator speed sensor is an AC voltage that varies in frequency and amplitude with increasing vehicle speed. The PM generator speed signal is sent to the instrument cluster electronic circuits. These specialized electronic circuits include a buffer amplifier circuit that converts the variable sine wave voltage from the speed sensor to an on/off signal that can be used by other electronic circuits to indicate a vehicle’s speed. The vehicle speed is then displayed by either an electronic needle-type speedometer or by numbers on a digital display.
ELECTRONIC ODOMETERS PURPOSE AND FUNCTION An odometer is a dash display that indicates the total miles traveled by the vehicle. Some dash displays also include a trip odometer that can be reset and used to record total
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(b) FIGURE 57–41 (a) Some odometers are mechanical and are operated by a stepper motor. (b) Many vehicles are equipped with an electronic odometer. REAL WORLD FIX Electronic Devices Cannot Swim The owner of a Dodge minivan complained that after the vehicle was cleaned inside and outside, the temperature gauge, fuel gauge, and speedometer stopped working. The vehicle speed sensor was checked and found to be supplying a square wave signal that changed with vehicle speed. A scan tool indicated a speed, yet the speedometer displayed zero all the time. Finally, the service technician checked the body computer to the right of the accelerator pedal and noticed that it had been wet, from the interior cleaning. Drying the computer did not fix the problem, but a replacement body computer fixed all the problems. The owner discovered that electronic devices do not like water and that computers cannot swim.
miles traveled on a trip or the distance traveled between fuel stops. Electronic dash displays can use either an electrically driven mechanical odometer or a digital display odometer to indicate miles traveled. On mechanical type odometers, a small electric motor, called a stepper motor, is used to turn the number wheels of a mechanical-style odometer. A pulsed voltage is fed to this stepper motor, which moves in relation to the miles traveled. SEE FIGURE 57–41.
Digital odometers use LED, LCD, or VTF displays to indicate miles traveled. Because total miles must be retained when the ignition is turned off or the battery is disconnected, a special electronic chip must be used that will retain the miles traveled. These special chips are called nonvolatile random-access memory (NVRAM). Nonvolatile means that the information stored in the electronic chip is not lost when electrical power is removed. Some vehicles use a chip called electronically erasable programmable read-only memory (EEPROM). Most digital odometers can read up to 999,999.9 miles or kilometers (km), and then the display indicates error. If the chip is damaged or exposed to static electricity, it may fail to operate and “error” may appear.
FUEL TANK PRESSURE SENSOR
ELECTRICAL CONNECTOR
SPEEDOMETER/ODOMETER SERVICE
If the speedometer and odometer fail to operate, check the following:
The speed sensor should be the first item checked. With the vehicle safely raised off the ground and supported, check vehicle speed using a scan tool. If a scan tool is not available, disconnect the wires from the speed sensor near the output shaft of the transmission. Connect a multimeter set on AC volts to the terminals of the speed sensor and rotate the drive wheels with the transmission in neutral. A good speed sensor should indicate approximately 2 volts AC if the drive wheels are rotated by hand.
If the speed sensor is working, check the wiring from the speed sensor to the dash cluster. If the wiring is good, the instrument panel (IP) should be sent to a specialty repair facility.
If the speedometer operates correctly but the mechanical odometer does not work, the odometer stepper motor, the number wheel assembly, or the circuit controlling the stepper motor is defective. If the digital odometer does not operate but the speedometer operates correctly, then the dash cluster must be removed and sent to a specialized repair facility. A replacement chip is available only through authorized sources; if the odometer chip is defective, the original number of miles must be programmed into the replacement chip.
FLOAT RESISTOR
FIGURE 57–42 A fuel tank module assembly that contains the fuel pump and fuel level sensor in one assembly.
ELECTRONIC FUEL LEVEL GAUGES OPERATION
Electronic fuel level gauges ordinarily use the same fuel tank sending unit as that used on conventional fuel gauges. The tank unit consists of a float attached to a variable resistor. As the fuel level changes, the resistance of the sending unit changes. As the resistance of the tank unit changes, the dash-mounted gauge also changes. The only difference between a digital fuel level gauge and a conventional needle type is in the display. Digital fuel level gauges can be either numerical (indicating gallons or liters remaining in the tank) or a bar graph display. SEE FIGURE 57–42. The diagnosis of a problem is the same as that described earlier for conventional fuel gauges. If the tests indicate that the dash unit is defective, usually the entire dash gauge assembly must be replaced.
NAVIGATION AND GPS PURPOSE AND FUNCTION The global positioning system (GPS) uses 24 satellites in orbit around the earth to provide signals for navigation devices. GPS is funded and controlled by the U.S.
FIGURE 57–43 Global positioning systems use 24 satellites in high earth orbit whose signals are picked up by navigation systems. The navigation system computer then calculates the location based on the position of the satellite overhead. Department of Defense (DOD). While the system can be used by anyone with a GPS receiver, it was designed for and is operated by the U.S. military. SEE FIGURE 57–43.
BACKGROUND The current global positioning system was developed after a civilian airplane from Korean Airlines, Flight 007, was shot down as it flew over Soviet territory in 1983. The system became fully operational in 1991. Civilians were granted use of GPS that same year, but with less accuracy than the system used by the military. Until 2000, the nonmilitary use of GPS was purposely degraded by a computer program called selection availability (S/A) built into the satellite transmission signals. After 2000, the S/A has been officially turned off, allowing nonmilitary users more accurate position information from the GPS receivers.
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FIGURE 57–44 A typical GPS display screen showing the location of the vehicle.
FIGURE 57–45 A typical navigation display showing various options. Some systems do not allow access to these functions if the vehicle is in gear and/or moving. TECH TIP
?
FREQUENTLY ASKED QUESTION
Window Tinting Can Hurt GPS Reception Most factory-installed navigation systems use a GPS antenna inside the rear back glass or under the rear package shelf. If a metalized window tint is applied to the rear glass, the signal strength from the GPS satellites can be reduced. If the customer concern includes inaccurate or nonfunctioning navigation, check for window tint.
Does the Government Know Where I Am? No. The navigation system uses signals from the satellites and uses the signals from three or more to determine position. If the vehicle is equipped with OnStar, then the vehicle position can be monitored by the use of the cellular telephone link to OnStar call centers. Unless the vehicle has a cellular phone connection to the outside world, the only people who will know the location of the vehicle are the persons inside the vehicle viewing the navigation screen.
TECH TIP Touch Screen Tip Most vehicle navigation systems use a touch screen for use by the driver (or passenger) to input information or other on-screen prompts. Most touch screens use infrared beams projected from the top and bottom plus across the screen to form a grid. The system detects where on the screen a finger is located by the location of the beams that are cut. Do not push harder on the display if the unit does not respond, or damage to the display unit may occur. If no response is detected when lightly depressing the screen, rotate the finger to cause the infrared beams to be cut.
NAVIGATION SYSTEM PARTS AND OPERATION
Navigation systems use the GPS satellites for basic location information. The navigation controller located in the rear of the vehicle uses other sensors, including a digitized map to display the location of the vehicle.
GPS satellite signals. These signals from at least three satellites are needed to locate the vehicle.
Yaw sensor. This sensor is often used inside the navigation unit to detect movement of the vehicle during cornering. This sensor is also called a “g” sensor because it measures force; 1 g is the force of gravity.
Vehicle speed sensor. This sensor input is used by the navigation controller to determine the speed and distance the vehicle travels. This information is compiled and compared to the digital map and GPS satellite inputs to locate the vehicle.
screen. If the telephone number of the business is known, the location can be displayed.) NOTE: Private residences or cellular telephone numbers are not included in the database of telephone numbers stored on the navigation system DVD.
Audio output/input. Voice-activated factory units use a builtin microphone at the center top of the windshield and the audio speakers speech output. Navigation systems include the following components.
1. Screen display SEE FIGURE 57–44. 2. GPS antenna 3. Navigation control unit, usually with map information on a DVD The DVD includes street names and the following information. 1. Points of interest (POI), including automated teller machines (ATMs), restaurants, schools, colleges, museums, shopping, and airports, as well as vehicle dealer locations. 2. Business addresses and telephone numbers, including hotels and restaurants (If the telephone number is listed in the business telephone book, it can usually be displayed on the navigation
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3. Turn-by-turn directions to addresses that are selected by: Points of interest (POI) Typed in using a keyboard shown on the display The navigation unit then often allows the user to select the fastest way to the destination, as well as the shortest way, or how to avoid toll roads. SEE FIGURE 57–45.
DIAGNOSIS AND SERVICE
For the correct functioning of the navigation system, three inputs are needed.
Location
Direction
Speed
FIGURE 57–46 A screen display of a navigation system that is unable to acquire usable signals from GPS satellites.
The navigation system uses the GPS satellite and map data to determine a location. Direction and speed are determined by the navigation computer from inputs from the satellite, plus the yaw sensor and vehicle speed sensor. The following symptoms may occur and be a customer complaint. Knowing how the system malfunctions helps to determine the most likely cause.
FIGURE 57–47 The three-button OnStar control is located on the inside rearview mirror. The left button (telephone handset icon) is pushed if a hands-free cellular call is to be made. The center button is depressed to contact an OnStar advisor and the right emergency button is used to request that help be sent to the vehicle’s location.
?
What Is Navigation Enhanced Climate Control?
If the vehicle icon jumps down the road, a fault with the vehicle speed (VS) sensor input is usually indicated.
Some vehicles, such as the Acura RL, use data from the navigation system to help control the automatic climate control system. Data about the location of the vehicle includes:
If the icon rotates on the screen, but the vehicle is not being driven in circles, a fault with the yaw sensor or yaw sensor input to the navigation controller is likely.
• Time and date. This information allows the automatic climate control system to determine where the sun is located. • Direction of travel. The navigation system can also help the climate control system determine the direction of travel.
If the icon goes off course and shows the vehicle on a road that it is not on, a fault with the GPS antenna is the most common reason for this situation.
Sometimes the navigation system itself will display a warning that views from the satellite are not being received. Always follow the displayed instructions. SEE FIGURE 57–46.
As a result of the input from the navigation system, the automatic climate control system can control cabin temperature in addition to various other sensors in the vehicle. For example, if the vehicle was traveling south in the late afternoon in July, the climate control system could assume that the passenger side of the vehicle would be warmed more by the sun than the driver’s side and could increase the airflow to the passenger side to help compensate for the additional solar heating.
ONSTAR PARTS AND OPERATION
FREQUENTLY ASKED QUESTION
OnStar is a system that includes
the following functions. 1. Cellular telephone 2. Global positioning antenna and computer OnStar is standard or optional on most General Motors vehicles and selected other brands and models, to help the driver in an emergency or to provide other services. The cellular telephone is used to communicate with the driver from advisors at service centers. The advisor at the service center is able to see the location of the vehicle as transmitted from the GPS antenna and computer system in the vehicle on a display. OnStar does not display the location of the vehicle to the driver unless the vehicle is also equipped with a navigation system. Unlike most navigation systems, the OnStar system requires a monthly fee. OnStar was first introduced in 1996 as an option on some Cadillac models. Early versions used a handheld cellular telephone while later units used a group of three buttons mounted on the inside rearview mirror and a hands-free cellular telephone. SEE FIGURE 57–47. The first version used analog cellular service while later versions used a dual mode (analog and digital) service until 2007. Since 2007, all OnStar systems use digital cellular service, which means that older systems that were analog only need to be upgraded.
The OnStar system includes the following features, which can vary depending on the level of service desired and cost per month.
Automatic notification of airbag deployment. If the airbag is deployed, the advisor is notified immediately and attempts to call the vehicle. If there is no reply, or if the occupants report an emergency, the advisor will contact emergency services and give them the location of the vehicle.
Emergency services. If the red button is pushed, OnStar immediately locates the vehicle and contacts the nearest emergency service agency.
Stolen vehicle location assistance. If a vehicle is reported stolen, a call center advisor can track the vehicle.
Remote door unlock. An OnStar advisor can send a cellular telephone message to the vehicle to unlock the vehicle if needed.
Roadside assistance. When called, an OnStar advisor can locate a towing company or locate a provider who can bring gasoline or change a flat tire.
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Accident assistance. An OnStar advisor is able to help with the best way to handle an accident. The advisor can supply a step-by-step checklist of the things that should be done plus call the insurance company, if desired.
Remote horn and lights. The OnStar system is tied into the lights and horn circuits so an advisor can activate them if requested to help the owner locate the vehicle in a parking lot or garage.
Vehicle diagnosis. Because the OnStar system is tied to the PCM, an OnStar advisor can help with diagnosis if there is a fault detected. The system works as follows:
The malfunction indicator light (MIL) (check engine) comes on to warn the driver that a fault has been detected.
The driver can depress the OnStar button to talk to an advisor and ask for a diagnosis.
The OnStar advisor will send a signal to the vehicle requesting the status from the powertrain control module (PCM), as well as the controller for the antilock brakes and the airbag module.
The vehicle then sends any diagnostic trouble codes to the advisor. The advisor can then inform the driver about the importance of the problem and give advice as to how to resolve the problem.
FIGURE 57–48 A typical view displayed on the navigation screen from the backup camera.
DIAGNOSIS AND SERVICE
The OnStar system can fail to meet the needs of the customer if any of the following conditions occur. 1. Lack of cellular telephone service in the area 2. Poor global positioning system (GPS) signals, which can prevent an OnStar advisor from determining the position of the vehicle 3. Transport of the vehicle by truck or ferry so that it is out of contact with the GPS satellite in order for an advisor to properly track the vehicle
If all of the above are okay and the problem still exists, follow service information diagnostic and repair procedures. If a new vehicle communication interface module (VCIM) is installed in the vehicle, the electronic serial number (ESN) must be tied to the vehicle. Follow service information instructions for the exact procedures to follow.
BACKUP CAMERA PARTS AND OPERATION
A backup camera is used to display the area at the rear of the vehicle in a screen display on the dash when the gear selector is placed in reverse. Backup cameras are also called reversing cameras or rearview cameras. Backup cameras are different from normal cameras because the image displayed on the dash is flipped so it is a mirror image of the scene at the rear of the vehicle. This reversing of the image is needed because the driver and the camera are facing in opposite directions. Backup cameras were first used in large vehicles with limited rearward visibility, such as motor homes. Many vehicles equipped with navigation systems today include a backup camera for added safety while backing. SEE FIGURE 57–48. The backup camera contains a wide-angle or fisheye lens to give the largest viewing area. Most backup cameras are pointed downward so that objects on the ground, as well as walls, are displayed. SEE FIGURE 57–49.
DIAGNOSIS AND SERVICE Faults in the backup camera system can be related to the camera itself, the display, or the connecting wiring. The main input to the display unit comes from the
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C H A P T ER 57
FIGURE 57–49 A typical fisheye-type backup camera usually located near the center on the rear of the vehicle near the license plate.
TECH TIP Check for Repainted Bumper The ultrasonic sensors embedded in the bumper are sensitive to paint thickness because the paint covers the sensors. If the system does not seem to be responding to objects, and if the bumper has been repainted, measure the paint thickness using a nonferrous paint thickness gauge. The maximum allowable paint thickness is 6 mils (0.006 inch or 0.15 mm).
transmission range switch which signals the backup camera when the transmission is shifted into reverse. To check the transmission range switch, perform the following: 1. Check if the backup (reverse) lights function when the gear selector is placed in reverse with the key on, engine off (KOEO). 2. Check that the transmission/transaxle is fully engaged in reverse when the selector is placed in reverse. Most of the other diagnosis involves visual inspection, including: 1. Check the backup camera for damage. 2. Check the screen display for proper operation. 3. Check that the wiring from the rear camera to the body is not cut or damaged. Always follow the vehicle manufacturer’s recommended diagnosis and repair procedures.
FIGURE 57–50 A typical backup sensor display located above the rear window inside the vehicle. The warning lights are visible in the inside rearview mirror.
BACKUP SENSORS COMPONENTS
Backup sensors are used to warn the driver if there is an object behind the vehicle while backing. The system used in General Motors vehicles is called rear park assist (RPA), and includes the following components.
Ultrasonic object sensors built into the rear bumper assembly
A display with three lights usually located inside the vehicle above the rear window and visible to the driver in the rearview mirror
An electronic control module that uses an input from the transmission range switch and lights the warning lamps needed when the vehicle gear selector is in reverse
OPERATION The three-light display includes two amber lights and one red light. The following lights are displayed depending on the distance from the rear bumper.
One amber lamp will light when the vehicle is in reverse and traveling at less than 3 mph (5 km/h) and the sensors detect an object 40 to 60 in. (102 to 152 cm) from the rear bumper. A chime also sounds once when an object is detected, to warn the driver to look at the rear parking assist display. SEE FIGURE 57–50.
FIGURE 57–51 The small round buttons in the rear bumper are ultrasonic sensors used to sense distance to an object. 3. A signal line, used to send and receive commands to and from the RPA module
DIAGNOSIS The rear parking assist control module is capable of detecting faults and storing diagnostic trouble codes (DTCs). If a fault has been detected by the control module, the red lamp flashes and the system is disabled. Follow service information diagnostic procedures because the rear parking assist module cannot usually be accessed using a scan tool. Most systems use the warning lights to indicate trouble codes.
LANE DEPARTURE WARNING SYSTEM PARTS AND OPERATION
The lane departure warning system (LDWS) uses cameras to detect if the vehicle is crossing over lane marking lines on the pavement. Some systems use two cameras, one mounted on each outside rearview mirror. Some systems use infrared sensors located under the front bumper to monitor the lane markings on the road surface. The system names also vary according to vehicle manufacturer, including: Honda/Acura: lane keep assist system (LKAS)
Two amber lamps light when the distance between the rear bumper and an object is between 20 and 40 in. (50 and 100 cm) and the chime will sound again.
Toyota/Lexus: lane monitoring system (LMS)
Two amber lamps and the red lamp light and the chime sounds continuously when the distance between the rear bumper and the object is between 11 and 20 in. (28 and 50 cm).
Nissan/Infinity: lane departure prevention (LDP) system
If the distance between the rear bumper and the object is less than 11 in. (28 cm), all indicator lamps flash and the chime will sound continuously. The ultrasonic sensors embedded in the rear bumper “fire” individually every 150 milliseconds (27 times per second). SEE FIGURE 57–51. The sensors fire and then receive a return signal and arm to fire again in sequence from the left sensor to the right sensor. Each sensor has the following three wires. 1. An 8 volt supply wire from the RPA module, used to power the sensor 2. A reference low or ground wire
General Motors: lane departure warning (LDW) Ford: lane departure warning (LDW) If the cameras detect that the vehicle is starting to cross over a lane dividing line, a warning chime will sound or a vibrating mechanism mounted in the driver’s seat cushion is triggered on the side where the departure is being detected. This warning will not occur if the turn signal is on in the same direction as detected. SEE FIGURE 57–52.
DIAGNOSIS AND SERVICE
Before attempting to service or repair a lane departure warning system fault, check service information for an explanation on how the system is supposed to work. If the system is not working as designed, perform a visual inspection of the sensors or cameras, checking for damage from road debris or evidence of body damage, which could affect the sensors. After a visual inspection, follow the vehicle manufacturer’s recommended diagnosis procedures to locate and repair the fault in the system.
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FIGURE 57–52 A lane departure warning system often uses cameras to sense the road lines and warns the driver if the vehicle is not staying within the lane, unless the turn signal is on.
ELECTRONIC DASH INSTRUMENT DIAGNOSIS AND TROUBLESHOOTING If one or more electronic dash gauges do not work correctly, first check the WOW display that lights all segments to full brilliance whenever the ignition switch is first switched on. If all segments of the display do not operate, then the entire electronic cluster must be replaced in most cases. If all segments operate during the WOW display but do not function correctly afterwards, the problem is most often a defective sensor or defective wiring to the sensor. All dash instruments except the voltmeter use a variable-resistance unit as a sensor for the system being monitored. Most new-vehicle dealers are required to purchase essential test equipment, including a test unit that permits the technician to insert various fixed-resistance values in the suspected circuit. For example, if a 45 ohm resistance is put into the fuel gauge circuit that reads from 0 to 90 ohms, a properly operating dash unit should indicate one-half tank. The same tester can produce a fixed signal to test the operation of the speedometer and tachometer. If this type of special test equipment is not available, the electronic dash instruments can be tested using the following procedure.
TECH TIP Keep Stock Overall Tire Diameter Whenever larger (or smaller) wheels or tires are installed, the speedometer and odometer calibration are also thrown off. This can be summarized as follows: • Larger diameter tires. The speed showing on the speedometer is slower than the actual speed. The odometer reading will show fewer miles than actual. • Smaller diameter tires. The speed showing on the speedometer is faster than the actual speed. The odometer reading will show more miles than actual. General Motors trucks can be recalibrated with a recalibration kit (1988–1991) or with a replacement controller assembly called a digital ratio adapter controller (DRAC) located under the dash. It may be possible to recalibrate the speedometer and odometer on earlier models, before 1988, or vehicles that use speedometer cables by replacing the drive gear in the transmission. Check service information for the procedure on the vehicle being serviced.
1. With the ignition switched off, unplug the wire(s) from the sensor for the function being tested. For example, if the oil pressure gauge is not functioning correctly, unplug the wire connector at the oil pressure sending unit. 2. With the sensor wire unplugged, turn the ignition switch on and wait until the WOW display stops. The display for the affected unit should show either fully lighted segments or no lighted segments, depending on the make of the vehicle and the type of sensor. 3. Turn the ignition switch off. Connect the sensor wire lead to ground and turn the ignition switch on. After the WOW display, the display should be the opposite (either fully on or fully off) of the results in step 2.
TESTING RESULTS If the electronic display functions fully on and fully off with the sensor unplugged and then grounded, the problem is a defective sensor. If the electronic display fails to function fully on and fully off when the sensor wire(s) are opened and grounded, the problem is usually in the wiring from the sensor to the electronic dash or it is a defective electronic cluster. CAUTION: Whenever working on or near any type of electronic dash display, always wear a wire attached to your wrist (wrist strap) connected to a good body ground to prevent damaging the electronic dash with static electricity.
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C H A P T ER 57
MAINTENANCE REMINDER LAMPS Maintenance reminder lamps indicate that the oil should be changed or that other service is required. There are numerous ways to extinguish a maintenance reminder lamp. Some require the use of a special tool. Always check the owner manual or service information for the exact procedure for the vehicle being serviced. For example, to reset the oil service reminder light on many General Motors vehicles, you have to perform the following: STEP 1
Turn the ignition key on (engine off).
STEP 2
Depress the accelerator pedal three times and hold it down on the fourth.
STEP 3
When the reminder light flashes, release the accelerator pedal.
STEP 4
Turn the ignition key to the off position.
STEP 5
Start the engine and the light should be off.
FUEL GAUGE DIAGNOSIS
1
Observe the fuel gauge. This General Motors vehicle shows an indicated reading of slightly above one-half tank.
3
From the service manual, the connector for the fuel gauge-sending unit was located under the vehicle near the rear. A visual inspection indicated that the electrical wiring and connector were not damaged or corroded.
5
Following the schematic in the service manual the sending unit resistance can be measured between the pink and the black wires in the connector.
2
Consult the factory service manual for the specifications, wire color, and recommended test procedure.
4
To test resistance of the sending unit (tank unit) use a digital multimeter and select ohms (Ω).
6
The meter displays 50 ohms or slightly above the middle of the normal resistance value for the vehicle of 0 Ω (empty) to 90 Ω (full).
CONTINUED
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STEP BY STEP
7
To check if the dash unit can move, the connector is unplugged with the ignition key on (engine off).
9
After a couple of seconds, the needle disappears above the full reading. The open connector represented infinity ohms and normal maximum reading occurs when the tank unit reads 90 ohms. If the technician does not realize that the needle could disappear, an incorrect diagnosis could be made.
11 644
A check of a dash unit indicated that the needle does accurately read empty.
C H A P T ER 57
8
As the connector is disconnected, the needle of the dash unit moves toward full.
10
To check if the dash unit is capable of reading empty, a fuse jumper wire is connected between the signal wire at the dash end of the connector and a good chassis ground.
12
After testing, reconnect the electrical connectors and verify for proper operation of the fuel level gauge.
REVIEW QUESTIONS 1. How does a stepper motor analog dash gauge work?
4. How do you test the dash unit of a fuel gauge?
2. What are LED, LCD, VTF, and CRT dash displays? Describe each.
5. How does a navigation system determine the location of the vehicle?
3. How do you diagnose a problem with a red brake warning lamp?
CHAPTER QUIZ 1. Two technicians are discussing a fuel gauge on a General Motors vehicle. Technician A says that if the ground wire connection to the fuel tank sending unit becomes rusty or corroded, the fuel gauge will read lower than normal. Technician B says that if the power lead to the fuel tank sending unit is disconnected from the tank unit and grounded (ignition on), the fuel gauge should go to empty. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 2. If an oil pressure warning lamp on a General Motors vehicle is on all the time, yet the engine oil pressure is normal, the problem could be a ______________. a. Defective (shorted) oil pressure sending unit (sensor) b. Defective (open) oil pressure sending unit (sensor) c. Wire shorted-to-ground between the sending unit (sensor) and the dash warning lamp d. Both a and c 3. When the oil pressure drops to between 3 and 7 psi, the oil pressure lamp lights by ______________. a. Opening the circuit b. Shorting the circuit c. Grounding the circuit d. Conducting current to the dash lamp by oil 4. A brake warning lamp on the dash remains on whenever the ignition is on. If the wire to the pressure differential switch (usually a part of a combination valve or built into the master cylinder) is unplugged, the dash lamp goes out. Technician A says that this is an indication of a fault in the hydraulic brake system. Technician B says that the problem is probably due to a stuck parking brake cable switch. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 5. A customer complains that every time the lights are turned on in the vehicle, the dash display dims. What is the most probable explanation? a. Normal behavior for LED dash displays b. Normal behavior for VTF dash displays c. Poor ground in lighting circuit causing a voltage drop to the dash lamps d. Feedback problem most likely caused by a short-tovoltage between the headlights and dash display
6. Technician A says that LCDs may be slow to work at low temperatures. Technician B says that an LCD dash display can be damaged if pressure is exerted on the front of the display during cleaning. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 7. Technician A says that backup sensors use LEDs to detect objects. Technician B says that a backup sensor will not work correctly if the paint is thicker than 0.006 in. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 8. Technician A says that metal-type tinting can affect the navigation system. Technician B says most navigation systems require a monthly payment for use of the GPS satellite. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 9. Technician A says that the data displayed on the dash can come from the engine computer. Technician B says that the entire dash assembly may have to be replaced even if just one unit fails. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 10. How does changing the size of the tires affect the speedometer reading? a. A smaller diameter tire causes the speedometer to read faster than actual speed and more than actual mileage on the odometer. b. A smaller diameter tire causes the speedometer to read slower than the actual speed and less than the actual mileage on the odometer. c. A larger diameter tire causes the speedometer to read faster than the actual speed and more than the actual mileage on the odometer. d. A larger diameter tire causes the speedometer to read slower than the actual speed and more than the actual mileage on the odometer.
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chapter
58
HORN, WIPER, AND BLOWER MOTOR CIRCUITS
OBJECTIVES: After studying Chapter 58, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “G” (Horn and Wiper/Washer Diagnosis and Repair) and content area “H” (Accessories Diagnosis and Repair). • Describe how the horn operates. • List the components of a wiper circuit. • Explain how the blower motor can run at different speeds. • Discuss how to diagnosis faults in the horn, wiper, and blower motor circuits. KEY TERMS: Horns 646 • Pulse wipers 649 • Rain sense wipers 653 • Series-wound field 649 • Shunt field 649 • Variable-delay wipers 649 • Windshield wipers 648
HORNS PURPOSE AND FUNCTION
Horns are electric devices that emit a loud sound used to alert other drivers or persons in the area. Horns are manufactured in several different tones ranging from 1,800 to 3,550 Hz. Vehicle manufacturers select from various horn tones for a particular vehicle sound. SEE FIGURE 58–1. When two horns are used, each has a different tone when operated separately, yet the sound combines when both are operated.
HORN CIRCUITS
Automotive horns usually operate on full battery voltage wired from the battery, through a fuse, switch, and then to the horns. Most vehicles use a horn relay. With a relay, the horn button on the steering wheel or column completes a circuit to ground that closes a relay, and the heavy current flow required by the horn then travels from the relay to the horn. Without a horn relay, the high current of the horns must flow through the steering wheel horn switch. SEE FIGURE 58–2. The horn relay is also connected to the body control module, which “beeps” the horn when the vehicle is locked or unlocked, using the key fob remote.
FIGURE 58–1 Two horns are used on this vehicle. Many vehicles use only one horn, often hidden underneath the vehicle.
HORN RELAY
HORN OPERATION
A vehicle horn is an actuator that converts an electrical signal to sound. The horn circuit includes an armature (a coil of wire) and contacts that are attached to a diaphragm. When energized, the armature causes the diaphragm to move up which then opens a set of contact points that de-energize the armature circuit. As the diaphragm moves down, the contact points close, reenergize the armature circuit, and the diaphragm moves up again. This rapid opening and closing of the contact points causes the diaphragm to vibrate at an audible frequency. The sound created by the diaphragm is magnified as it travels through a trumpet attached to the diaphragm chamber. Most horn systems typically use one or two horns, but some have up to four. Those with multiple horns use both high- and low-pitch units to achieve a harmonious tone. Only a high-pitched unit is used in single-horn applications. The horn assembly is marked with an “H” or “L” for pitch identification.
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C H A P T E R 58
HORNS
12V
HORN BUTTON
FIGURE 58–2 A typical horn circuit. Note that the horn button completes the ground circuit for the relay.
HORN SYSTEM DIAGNOSIS
There are three types of horn
failure.
No horn operation
Intermittent operation
Constant operation
Weak or low volume sound
CORE SUPPORT MOUNTING BOLT
If a horn does not operate at all, check for the following:
Burned fuse or fusible link
Open circuit
Defective horn
Faulty relay
Defective horn switch
Poor ground (horn mounting)
Corroded or rusted electrical connector
HORN
CORE SUPPORT
RIGHT
MOUNTING BOLT HORN
If a horn operates intermittently, check for the following:
Loose contact at the switch
Loose, frayed, or broken wires
Defective relay
HORN SOUNDS CONTINUOUSLY
A horn that sounds continuously and cannot be shut off is caused by horn switch contacts that are stuck closed, or a short-to-ground on the control circuit. This may be the result of a defective horn switch or a faulty relay. Stuck relay contacts keep the circuit complete so the horn sounds constantly. Disconnect the horn and check continuity through the horn switch and relay to locate the source of the problem.
CROSSMEMBER
If the horn works, the problem is in the circuit supplying current to the horn.
If the horn does not work, the horn itself could be defective or the mounting bracket may not be providing a good ground.
HORN SERVICE
When a horn malfunctions, circuit tests are made to determine if the horn, relay, switch, or wiring is the source of the failure. Typically, a digital multimeter (DMM) is used to perform voltage drop and continuity checks to isolate the failure.
Switch and relay. A momentary contact switch is used to sound the horn. The horn switch is mounted to the steering wheel in the center of the steering column on some models, and is part of a multifunction switch installed on the steering column. CAUTION: If steering wheel removal is required for diagnosis or repair of the horn circuit, follow service information procedures for disarming the airbag circuit prior to steering wheel removal, and for the specified test equipment to use. On most late-model vehicles, the horn relay is located in a centralized power distribution center along with other relays, circuit breakers, and fuses. The horn relay bolts onto an inner
LEFT
FIGURE 58–3 Horns typically mount to the radiator core support or bracket at the front of the vehicle.
fender or the bulkhead in the engine compartment of older vehicles. Check the relay to determine if the coil is being energized and if current passes through the power circuit when the horn switch is depressed. Obtain an electrical schematic of the horn circuit and use a voltmeter to test input, output, and control voltage.
INOPERATIVE HORN
To help determine the cause of an inoperative horn, use a fused jumper wire and connect one end to the positive post of the battery and the other end to the wire terminal of the horn itself. Also use a fused jumper wire to substitute a ground path to test or confirm a potential bad ground circuit. If the horn works with jumper wires connected, check ground wires and connections.
CROSSMEMBER
Circuit testing. Circuit testing involves the following steps. STEP 1
Make sure the fuse or fusible link is good before attempting to troubleshoot the circuit.
STEP 2
Check that the ground connections for the horn are clean and tight. Most horns ground to the chassis through the mounting bolts. High ground circuit resistance due to corrosion, road dirt, or loose fasteners may cause no, or intermittent, horn operation.
STEP 3
On a system with a relay, test the power output circuit and the control circuit. Check for voltage available at the horn, voltage available at the relay, and continuity through the switch. When no relay is used, there are two wires leading to the horn switch, and a connection to the steering wheel is made with a double contact slip ring. Test points on this system are similar to those of a system with a relay, but there is no control circuit.
HORN REPLACEMENT
Horns are generally mounted on the radiator core support by bolts and nuts or sheet metal screws. It may be necessary to remove the grille or other parts to access the horn mounting screws. If a replacement horn is required, attempt to use a horn of the same tone as the original. The tone is usually indicated by a number or letter stamped on the body of the horn. To replace a horn, simply remove the fasteners and lift the old horn from its mounting bracket. Clean the attachment area on the mounting bracket and chassis before installing the new horn. Some models use a corrosion-resistant mounting bolt to ensure a ground connection. SEE FIGURE 58–3.
HORN, WIPER, AND BLOWER MOTOR CIRCUITS
647
BATT A0
RUN-ACC A31
POWER DISTRIBUTION CENTER
JUNCTION BLOCK
C2
WIPER HIGH/LOW RELAY (IN PDC)
INTERMITTENT WIPER RELAY (IN PDC)
WINDSHIELD WIPER MOTOR
M
S109
G111 C1
C1
C1 BODY CONTROL MODULE
FIGURE 58–4 A circuit diagram is necessary to troubleshoot a windshield wiper problem.
WINDSHIELD WIPER AND WASHER SYSTEM PURPOSE AND FUNCTION
Windshield wipers are used to keep the viewing area of the windshield clean of rain. Windshield wiper systems and circuits vary greatly between manufacturers as well as between models. Some vehicles combine the windshield wiper and windshield washer functions into a single system. Many minivans and sport utility vehicles (SUVs) also have a rear window wiper and washer system that works independently of the windshield system. In spite of the design differences, all windshield
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and rear window wiper and washer systems operate in a similar fashion.
COMPUTER CONTROLLED
Most wipers since the 1990s have used the body computer to control the actual operation of the wiper. The wiper controls are simply a command to the computer. The computer may also turn on the headlights whenever the wipers are on, which is the law in some states. SEE FIGURE 58–4.
WIPER AND WASHER COMPONENTS
A typical combination wiper and washer system consists of the following:
Wiper motor
Gearbox
GEAR AND TUBE ASSEMBLY DRIVE PAWL
LINKAGE
INTERMEDIATE GEAR
FIGURE 58–6 A typical wiper motor with the housing cover removed. The motor itself has a worm gear on the shaft that turns the small intermediate gear, which then rotates the gear and tube assembly, which rotates the crank arm (not shown) that connects to the wiper linkage.
RETAINING BOLT
ELECTRONIC CONNECTOR
WIPER MOTOR
FIGURE 58–5 The motor and linkage bolt to the body and connect to the switch with a wiring harness.
Wiper arms and linkage
Washer pump
Hoses and jets (nozzles)
Fluid reservoir
Combination switch
Wiring and electrical connectors
Electronic control module
The motor and gearbox assembly is wired to the wiper switch on the instrument panel or steering column or to the wiper control module. SEE FIGURE 58–5. Some systems use either a one- or two-speed wiper motor, whereas others have a variable-speed motor.
WINDSHIELD WIPER MOTORS
The windshield wipers ordinarily use a special two-speed electric motor. Most are compoundwound motors, a motor type, which provides for two different speeds.
Series-wound field
Shunt field
One speed is achieved in the series wound field and the other speed in the shunt wound field. The wiper switch provides the necessary electrical connections for either motor speed. Switches in the mechanical wiper motor assembly provide the necessary operation for “parking” and “concealing” of the wipers. SEE FIGURE 58–6 for a typical wiper motor assembly.
PAWL SPRING
Wiper motor operation. Most wiper motors use a permanent magnet motor with a low speed ⫹ brush and a high speed ⫹ brush. The brushes connect the battery to the internal windings of the motor, and the two brushes provide for two different motor speeds. The ground brush is directly opposite the low-speed brush. The high-speed brush is off to the side of the lowspeed brush. When current flows through the high-speed brush, there are fewer turns on the armature between the hot and ground brushes, and therefore the resistance is less. With less resistance, more current flows and the armature revolves faster. SEE FIGURES 58–7 AND 58–8.
Variable wipers. The variable-delay wipers (also called pulse wipers) use an electronic circuit with a variable resistor that controls the time of the charge and discharge of a capacitor. The charging and discharging of the capacitor controls the circuit for the operation of the wiper motor. SEE FIGURE 58–9.
HIDDEN WIPERS
Some vehicles are equipped with wipers that become hidden when turned off. These wipers are also called depressed wipers. The gearbox has an additional linkage arm to provide depressed parking for hidden wipers. This link extends to move the wipers into the park position when the motor turns in reverse of operating direction. With depressed park, the motor assembly includes an internal park switch. The park switch completes a circuit to reverse armature polarity in the motor when the windshield wiper switch is turned off. The park circuit opens once the wiper arms are in the park position. Instead of a depressed park feature, some systems simply extend the cleaning arc below the level of the hood line.
WINDSHIELD WIPER DIAGNOSIS
Windshield wiper failure may be the result of an electrical fault or a mechanical problem, such as binding linkage. Generally, if the wipers operate at one speed setting but not another, the problem is electrical. To determine if there is an electrical or mechanical problem, access the motor assembly and disconnect the wiper arm linkage from the motor and gearbox. Depending on the type of vehicle, this procedure may involve:
Removing body trim panels from the covered areas at the base of the windshield to gain access to the linkage connectors
Switching the motor on to each speed (If the motor operates at all speeds, the problem is mechanical. If the motor still does not operate, the problem is electrical.)
If the wiper motor does not run at all, check for the following:
Grounded or inoperative switch
Defective motor
Circuit wiring fault
Poor electrical ground connection
If the motor operates but the wipers do not, check for the following:
Stripped gears in the gearbox or stripped linkage connection
Loose or separated motor-to-gearbox connection
Loose linkage to the motor connection
HORN, WIPER, AND BLOWER MOTOR CIRCUITS
649
RUN – CLOSED BY RELAY PARK – OPENED BY MECHANICAL LEVER PARK SWITCH
OFF LO HI
FUSE
FROM IGNITION SWITCH
LOW-SPEED BRUSH
WIPER ARMATURE HIGH-SPEED BRUSH MOTOR
WASH WASHER MOTOR WIPER CONTROL (MULTI FUNCTION LEVER)
FIGURE 58–7 A wiring diagram of a two-speed windshield wiper circuit using a three-brush, two-speed motor. The dashed line for the multifunction lever indicates that the circuit shown is only part of the total function of the steering column lever.
WIPER CONTROL SWITCH
PARK SWITCH HI MED LO
SWITCH MUST BE GROUNDED
SERIES FIELD
SHUNT FIELD
WIPER MOTOR ARMATURE WIPER MOTOR
FIGURE 58–8 A wiring diagram of a three-speed windshield wiper circuit using a two-brush motor, but both a series-wound and a shunt field coil. If the motor does not shut off, check for the following:
Defective park switch inside the motor
Defective wiper switch
Poor ground connection at the wiper switch
WINDSHIELD WIPER TESTING
When the wiper motor does not operate with the linkage disconnected, perform the following steps to determine the fault. SEE FIGURE 58–10. To test the wiper system, perform the following steps. STEP 1
Refer to the circuit diagram or a connector pin chart for the vehicle being serviced to determine the test points for voltage measurements.
STEP 2
Switch the ignition on and set the wiper switch to a speed at which the motor does not operate.
STEP 3
Check for battery voltage available at the appropriate wiper motor terminal for the selected speed. If voltage is available to the motor, an internal motor problem is indicated. No voltage available indicates a switch or circuit failure.
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?
FREQUENTLY ASKED QUESTION
How Do Wipers Park? Some vehicles have wiper arms that park lower than the normal operating position so that they are hidden below the hood when not in operation. This is called a depressed park position. When the wiper motor is turned off, the park switch allows the motor to continue to turn until the wiper arms reach the bottom edge of the windshield. Then the park switch reverses the current flow through the wiper motor, which makes a partial revolution in the opposite direction. The wiper linkage pulls the wiper arms down below the level of the hood and the park switch is opened, stopping the wiper motor.
Hot in ACCY And RUN Hot in ACCY And RUN Rear Underhood ACC Compartment WIPERS Fuse Fuse Fuse Fuse Block Block A9
30 A
1 ORN
1040
10 A
P101
1 YEL 143 E5
C202 Windshield Wiper Switch
0.35 YEL 43 S403 0.35 YEL 43 A3
A1 Accessory Relay
High Low Min
Underhood Relay Center
High Low Min
High Low Min
High Low Min
Max Off Mist Washer Switch
Max Off Mist
Max Off Mist
91k 160k 300k 560k
B3
B1
1.2M
Max Off Mist
24k
Wash
0.35 BLK 50
Off
E6
E9
1 GRY
E8
E7 91
1 DK GRN/WHT
S210
P101
PASS THROUGH GROMMETS
C202
95 1 PPL 92 P101
1 GRY/BLK 91
1 YEL/BLK 196 Windshield
B
C
A C2 Wiper/
B
A C1 Cover
Wiper Motor
Park Switch
1 PNK/ BLK 94
Washer Module
M Solid State
F D
0.8 RED/BLK 228 C
E
P101
50
0.8 DK BLU/WHT 227 Windshield Washer Pump P101
G204
A
M
C2
2 BLK 750 S107 3 BLK 750 G101
B
FIGURE 58–9 A variable pulse rate windshield wiper circuit. Notice that the wiring travels from the passenger compartment through pass-through grommets to the underhood area.
PARK POSITION CIRCUIT BREAKER M PARK SWITCH
B
D
A
C
OTHER POSITION CIRCUIT BREAKER M
TERMINAL
D
A
C
A
D
B
Check for proper ground connections.
STEP 5
Check that battery voltage is available at the motor side of the wiper switch. If battery voltage is available, the circuit is open between the switch and motor. No voltage available indicates either a faulty switch or a power supply problem.
STEP 6
Check for battery voltage available at the power input side of the wiper switch. If voltage is available, the switch is defective. Replace the switch. No voltage available to the switch indicates a circuit problem between the battery and switch.
WINDSHIELD WIPER SERVICE
PARK SWITCH
B
STEP 4
C
OPERATION SPEED
C
LOW
A
HIGH
FIGURE 58–10 A wiper motor connector pin chart.
Wiper motors are replaced if defective. The motor usually mounts on the bulkhead (firewall). Bulkhead-mounted units are accessible from under the hood, while the cowl panel needs to be removed to service a motor mounted in the cowl. SEE FIGURE 58–11. After gaining access to the motor, removal is simply a matter of disconnecting the linkage, unplugging the electrical connectors, and unbolting the motor. Move the wiper linkage through its full travel by hand to check for any binding before installing the new motor. Rear window wiper motors are generally located inside the rear door panel of station wagons, or the rear hatch panel on vehicles with a hatchback or liftgate. SEE FIGURE 58–12. After removing the trim panel covering the motor, replacement is essentially the same as replacing the front wiper motor. Wiper control switches are either installed on the steering column or on the instrument panel.
HORN, WIPER, AND BLOWER MOTOR CIRCUITS
651
HOT IN ACCY OR RUN WIPER FUSE 25AMP .8 WHT
.8 WHT
C100B .8 WHT
COWL PANEL
AND PUMP ASSEMBLY (RELAY OPENS MECHANICALLY WHEN WIPERS PARK)
GEARBOX RELAY
WIPER MOTOR ASSEMBLY
WIPER-WASHER MOTOR
PULSE WIPE TIMER
PULSE RELAY MOTOR
1 SOLID STATE 3 2 .8 PNK
PLENUM
.8 PPL
20 OHM RESISTOR
C100B .8 PPL
.8 DK GRN
.8 PNK
.8 GRY C100B
.8 GRY DELAY
OFF
REAR WIPER MOTOR
HI
OFF
HI
DELAY RHEOSTAT
WASH SWITCH
FIGURE 58–11 The wiper motor and linkage mount under the cowl panel on many vehicles.
LO
LO
LO
SERIES FIELD ARMATURE SHUNT FIELD CIRCUIT BREAKER
HI
OFF
.8 3 BLK BLK S220
WIPER WASHER
G110
CONTROL
1 RATCHET RELEASE SOLENOID (OPERATED WHEN WASH SWITCH DEPRESSED) 2 WASHER OVERRIDE SWITCH (CLOSED DURING WASH CYCLE) 3 HOLDING SWITCH (OPEN AT THE END OF EACH SWEEP)
FIGURE 58–13 Circuit diagram of a rheostat-controlled, electronically timed interval wiper.
STEP 2
Refer to a wiring diagram of the switch to determine how current is routed through it to the motor in the different positions.
STEP 3
Disconnect the switch and use fused jumper wires to apply power directly to the motor on the different speed circuits. • If the motor now runs, the problem is in the switch or module. • Check for continuity in the circuit for each speed through the control-to-ground if the wiper motor runs at some, but not all, speeds.
FIGURE 58–12 A single wiper arm mounts directly to the motor on most rear wiper applications.
Steering column wiper switches, which are operated by controls on the end of a switch stalk (usually called a multifunction switch), require partial disassembly of the steering column for replacement.
WINDSHIELD WASHER OPERATION PULSE WIPE SYSTEMS
Windshield wipers may also incorporate a delay, or intermittent operation, feature commonly called pulse wipe. The length of the delay, or the frequency of the intermittent operation, is adjustable on some systems. Pulse wipe systems may rely on simple electrical controls, such as a variable-resistance switch, or be controlled electronically through a control module. With any electronic control system, it is important to follow the diagnosis and test procedures recommended by the manufacturer for that specific vehicle. A typical pulse, or interval, wiper system uses either a governor or a solid-state module that contains either a variable resistor or rheostat and capacitor. The module connects into the electrical circuitry between the wiper switch and wiper motor. The variable resistor or rheostat controls the length of the interval between wiper pulses. A solid-state pulse wipe timer regulates the control circuit of the pulse relay to direct current to the motor at the prescribed interval. SEE FIGURE 58–13. The following troubleshooting procedure applies to most models.
STEP 1
652
If the wipers do not run at all, check the wiper fuse, fusible link, or circuit breaker and verify that voltage is available to the switch.
CHAPTER 58
Most vehicles use a positive-displacement or centrifugal-type washer pump located in the washer reservoir. A momentary contact switch, which is often part of a steering column–mounted combination switch assembly, energizes the washer pump. Washer pump switches are installed either on the steering column or on the instrument panel. The nozzles can be located on the bulkhead or in the hood depending on the vehicle.
WINDSHIELD WASHER DIAGNOSIS
Inoperative windshield
washers may be caused by the following:
Blown fuse or open circuit
Empty reservoir
Clogged nozzle
Broken, pinched, or clogged hose
Loose or broken wire
Blocked reservoir screen
Leaking reservoir
Defective pump
To diagnose the washer system, follow service information procedures that usually include the following steps.
TECH TIP Use a Scan Tool to Check Accessories
SCREW
CLIP
Most vehicles built since 2000 can have the lighting and accessory circuits checked using a scan tool. A technician can use the following: • Factory scan tool, such as: • Tech 2 or Multiple Diagnostic Interface (MDI) (General Motors vehicle) • DRB III or Star Scan or Star Mobile or WiTech (ChryslerJeep vehicles) • New Generation Star or IDS (Ford) • Honda Diagnostic System (HDS) • TIS Tech Stream (Toyota/Lexus) • Enhanced aftermarket scan tool that has body bidirectional control capability, including:
HOSE
• Snap-on Modis, Solus, or Verus • OTC Genisys • Autoengenuity
RESERVOIR
Using a bidirectional scan tool allows the technician to command the operation of electrical accessories such as windows, lights, and wipers. If the circuit operates correctly when commanded by the scan tool and does not function using the switche(s), follow service information instructions to diagnose the switch circuits.
FIGURE 58–14 Disconnect the hose at the pump and operate the switch to check a washer pump. RESERVOIR DRY LUBE HERE MOTOR ASSEMBLY
STEP 1
To quick check any washer system, make sure the reservoir has fluid and is not frozen, and then disconnect the pump hose and operate the washer switch. NOTE: Always use good-quality windshield washer fluid from a closed container to prevent contaminated fluid from damaging the washer pump. Radiator antifreeze (ethylene glycol) should never be used in any windshield wiper system.
ALIGN HAND PRESS COMPONENTS TOGETHER RETAINING RING
FIGURE 58–15 Washer pumps usually install into the reservoir and are held in place with a retaining ring.
SEE FIGURE 58–14. STEP 2
If fluid squirts from the pump, the delivery system is at fault, not the motor, switch, or circuitry.
STEP 3
If no fluid squirts from the pump, the problem is most likely a circuit failure, defective pump, or faulty switch.
STEP 4
A clogged reservoir screen also may be preventing fluid from entering the pump.
WINDSHIELD WASHER SERVICE
When a fluid delivery
problem is indicated, check for:
Blocked, pinched, broken, or disconnected hose
Clogged nozzles
Blocked washer pump outlet
If the pump motor does not operate, check for battery voltage available at the pump while operating the washer switch. If voltage is available and the pump does not run, check for continuity on the pump ground circuit. If there is no voltage drop on the ground circuit, replace the pump motor. If battery voltage is not available at the motor, check for power through the washer switch. If voltage is available at and through the switch, there is a problem in the wiring between the switch and pump. Perform voltage drop tests to locate the fault. Repair the wiring as needed and retest.
Washer motors are not repairable and are simply replaced if defective. Centrifugal or positive-displacement pumps are located on or inside the washer reservoir tank or cover and secured with a retaining ring or nut. SEE FIGURE 58–15.
RAIN SENSE WIPER SYSTEM PARTS AND OPERATION
Rain sense wiper systems use a sensor located at the top of the windshield on the inside to detect rain droplets. This sensor is called the rain sense module (RSM) by General Motors. It determines and adjusts the time delay of the wiper based on how much moisture it detects on the windshield. The wiper switch can be left on the sense position all of the time and if no rain is sensed, the wipers will not swipe. SEE FIGURES 58–16 AND 58–17. The control knob is rotated to the desired wiper sensibility level. The microprocessor in the RSM sends a command to the body control module (BCM). RSM is a triangular-shaped black plastic housing. Fine openings on the windshield side of the housing are
HORN, WIPER, AND BLOWER MOTOR CIRCUITS
653
SQUIRREL CAGE BLOWER
BLOWER MOTOR
FIGURE 58–16 A typical rain sensing module located on the inside of the windshield near the inside rearview mirror.
RAIN DROP
FIGURE 58–18 A squirrel cage blower motor. A replacement blower motor usually does not come equipped with the squirrel cage blower, so it has to be switched from the old motor.
4. Defogging 5. Venting of the passenger compartment WINDSHIELD
LASER LED
LIGHT SENSOR
The motor turns a squirrel cage-type fan. A squirrel cage-type fan is able to move air without creating a lot of noise. The fan switch controls the path that the current follows to the blower motor. SEE FIGURE 58–18.
PHOTO DIODE AMBIENT LIGHT SENSOR
FIGURE 58–17 The electronics in the rain sense wiper module can detect the presence of rain drops under various lighting conditions. fitted with eight convex clear plastic lenses. The unit contains four infrared (IR) diodes, two photocells, and a microprocessor. The IR diodes generate IR beams that are aimed by four of the convex optical lenses near the base of the module through the windshield glass. Four additional convex lenses near the top of the RSM are focused on the IR light beam on the outside of the windshield glass and allow the two photocells to sense changes in the intensity of the IR light beam. When sufficient moisture accumulates, the RSM detects a change in the monitored IR light beam intensity. The RSM processes the signal BCM over the data BUS to command a swipe of the wiper.
DIAGNOSIS AND SERVICE
If there is a complaint about the rain sense wipers not functioning correctly, check the owner manual to be sure that they are properly set and adjusted. Also, verify that the windshield wipers are functioning correctly on all speeds before diagnosing the rain sensor circuits. Always follow the vehicle manufacturer’s recommended diagnosis and testing procedures.
BLOWER MOTOR PURPOSE AND FUNCTION air inside the vehicle for: 1. Air conditioning 2. Heat 3. Defrosting
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The same blower motor moves
PARTS AND OPERATION
The motor is usually a permanent magnet, one-speed motor that operates at its maximum speed with full battery voltage. The switch gets current from the fuse panel with the ignition switch on, and then directs full battery voltage to the blower motor for high speed and to the blower motor through resistors for lower speeds.
VARIABLE SPEED CONTROL
The fan switch controls the path of current through a resistor pack to obtain different fan speeds of the blower motor. The electrical path can be:
Full battery voltage for high-speed operation
Through one or more resistors to reduce the voltage and the current to the blower motor which then rotates at a slower speed
The resistors are located near the blower motor and mounted in the duct where the airflow from the blower can cool the resistors. The current flow through the resistor is controlled by the switch and often uses a relay to carry the heavy current (10 to 12 amperes) needed to power the fan. Normal operation includes:
Low speed. Current flows through three resistors in series to drop the voltage to about 4 volts and 4 amperes.
Medium speed. Current is directed through two resistors in series to lower the voltage to about 6 volts and 6 amperes.
Medium-high speed. Current is directed through one resistor resulting in a voltage of about 9 volts and 9 amperes.
High speed. Full battery voltage, usually through a relay, is applied to the blower motor resulting in a current of about 12 amperes.
SEE FIGURES 58–19 AND 58–20. NOTE: Most Ford and some other vehicles place the blower motor resistors on the ground side of the motor circuit. The location of the resistors does not affect the operation because they are connected in series.
FAN CONTROL SWITCH
30-A FUSE
(R1)
MED LO
LO
IGNITION SWITCH
A
HI
B BLOWER (R2) MOTOR RESISTORS C
MED HI
BATTERY (R3) D FUSIBLE LINK
HIGH-SPEED BLOWER RELAY MOTOR
FIGURE 58–19 A typical blower motor circuit with four speeds. The three lowest fan speeds (low, medium-low, and medium-high) use the blower motor resistors to drop the voltage to the motor and reduce current to the motor. On high, the resistors are bypassed. The “high” position on the fan switch energizes a relay, which supplies the current for the blower on high through a fusible link.
TECH TIP The 20 Ampere Fuse Test
FIGURE 58–20 A typical blower motor resistor pack used to control blower motor speed. Some blower motor resistors are flat and look like a credit card and are called “credit card resistors”.
Most blower motors operate at about 12 A on high speed. If the bushings (bearings) on the armature of the motor become worn or dry, the motor turns more slowly. Because a motor also produces counterelectromotive force (CEMF) as it spins, a slower-turning motor will actually draw more amperes than a fast-spinning motor. If a blower motor draws too many amperes, the resistors or the electronic circuit controlling the blower motor can fail. Testing the actual current draw of the motor is sometimes difficult because the amperage often exceeds the permissible amount for most digital meters. One test recommended by General Motors Co. is to unplug the power lead to the motor (retain the ground on the motor) and use a fused jumper lead with one end connected to the battery’s positive terminal and the other end to the motor terminal. Use a 20 A fuse in the test lead, and operate the motor for several minutes. If the blower motor is drawing more than 20 A, the fuse will blow. Some experts recommend using a 15 A fuse. If the 15 A fuse blows and the 20 A fuse does not, then you know the approximate blower motor current draw.
FIGURE 58–21 A brushless DC motor that uses the body computer to control the speed. (Courtesy of Sammy’s Auto Service, Inc.)
Some blower motors are electronically controlled by the body control module (BCM) and include electronic circuits to achieve a variable speed. SEE FIGURE 58–21.
BLOWER MOTOR DIAGNOSIS
If the blower motor does not operate at any speed, the problem could be any of the following: 1. Defective ground wire or ground wire connection 2. Defective blower motor (not repairable; must be replaced) 3. Open circuit in the power-side circuit, including fuse, wiring, or fan switch
If the blower works on lower speeds but not on high speed, the problem is usually an inline fuse or high-speed relay that controls the heavy current flow for high-speed operation. The high-speed fuse or relay usually fails as a result of internal blower motor bushing wear, which causes excessive resistance to motor rotation. At slow blower speeds, the resistance is not as noticeable and the blower operates normally. The blower motor is a sealed unit, and if defective, must be replaced as a unit. The squirrel cage fan usually needs to be removed from the old motor and attached to the replacement motor. If the blower motor operates normally at high speed but not at any of the lower speeds, the problem could be melted wire resistors or a defective switch.
HORN, WIPER, AND BLOWER MOTOR CIRCUITS
655
The blower motor can be tested using a clamp-on DC ammeter.
SEE FIGURE 58–22. Most blower motors do not draw more than 15 A on high speed. A worn or defective motor usually draws more current than normal and could damage the blower motor resistors or blow a fuse if not replaced.
ELECTRICAL ACCESSORY SYMPTOM GUIDE The following list will assist technicians in troubleshooting electrical accessory systems.
FIGURE 58–22 Using a mini AC/DC clamp-on multimeter to measure the current draw of a blower motor.
Blower Motor Problem
Possible Causes and/or Solutions
Blower motor does not operate.
1. Blown fuse 2. Poor ground connection on blower motor 3. Defective motor (Use a fused jumper wire connected between the positive terminal of the battery and the blower motor power lead connection [lead disconnected] to check for blower motor operation.) 4. Defective control switch 5. Resistor block open or defective blower motor control module
Blower motor operates only on high speed.
1. Open in the resistors located in the air box near the blower motor 2. Stuck or defective high-speed relay 3. Defective blower motor control switch
Blower motor operates in lower speed(s) only, no high speed.
1. Defective high-speed relay or blower high-speed fuse
Windshield Wiper or Washer Problem
Possible Causes and/or Solutions
Windshield wipers are inoperative.
1. Blown fuse
NOTE: If the high-speed fuse blows a second time, check the current draw of the motor and replace the blower motor if the current draw is above specifications. Check for possible normal operation if the rear window defogger is not in operation; some vehicles electrically prevent simultaneous operation of the high-speed blower and rear window defogger to help reduce the electrical loads.
2. Poor ground on the wiper motor or the control switch 3. Defective motor or linkage problem Windshield wipers operate on high speed or low speed only.
1. Defective switch 2. Defective motor assembly 3. Poor ground on the wiper control switch
Windshield washers are inoperative.
1. Defective switch 2. Empty reservoir or clogged lines or discharge nozzles 3. Poor ground on the washer pump motor
Horn Problem
Possible Causes and/or Solutions
Horn(s) are inoperative.
1. Poor ground on horn(s) 2. Defective relay (if used); open circuit in the steering column 3. Defective horn (Use a fused jumper wire connected between the positive terminal of the battery and the horn [horn wire disconnected] to check for proper operation of the horn.)
Horn(s) produce low volume or wrong sound.
1. Poor ground at horn
Horn blows all the time.
1. Stuck horn relay (if used)
2. Incorrect frequency of horn
2. Short-to-ground in the wire to the horn button
656
CHAPTER 58
REVIEW QUESTIONS 1. What are the three types of horn failure? 2. How is the horn switch used to operate the horn?
4. Why does a defective blower motor draw more current (amperes) than a good motor?
3. How do you determine if a windshield wiper problem is electrical or mechanical?
CHAPTER QUIZ 1. Technician A says that a defective high-speed blower motor relay could prevent high-speed blower operation, yet allows normal operation at low speeds. Technician B says that a defective (open) blower motor resistor can prevent low-speed blower operation, yet permit normal high-speed operation. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 2. To determine if a windshield wiper problem is electrical or mechanical, the service technician should ________. a. Disconnect the linkage arm from the windshield wiper motor and operate the windshield wiper b. Check to see if the fuse is blown c. Check the condition of the wiper blades d. Check the washer fluid for contamination 3. A weak-sounding horn is being diagnosed. Technician A says that a poor ground connector at the horn itself can be the cause. Technician B says an open relay can be the cause. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 4. What controls the operation of a pulse wiper system? a. Resistor that controls current flow to the wiper motor b. Solid-state (electronic) module c. Variable-speed gem set d. Transistor 5. Which pitch horn is used for a single horn application? a. High pitch b. Low pitch
chapter
6. The horn switch on the steering wheel on a vehicle that uses a horn relay ________. a. Sends electrical power to the horns b. Provides the ground circuit for the horn c. Grounds the horn relay coil d. Provides power (12 V) to the horn relay 7. A rain sense wiper system uses a rain sensor that is usually mounted ________. a. Behind the grille b. Outside of the windshield at the top c. Inside the windshield at the top d. On the roof 8. Technician A says a blower motor can be tested using a fused jumper lead. Technician B says a blower motor can be tested using a clamp-on ammeter. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 9. A defective blower motor draws more current than a good motor because the ________. a. Speed of the motor increases b. CEMF decreases c. Airflow slows down, which decreases the cooling of the motor d. Both a and c 10. Windshield washer pumps can be damaged if ________. a. Pure water is used in freezing weather b. Contaminated windshield washer fluid is used c. Ethylene glycol (antifreeze) is used d. All of the above
ACCESSORY CIRCUITS
59 OBJECTIVES: After studying Chapter 59, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “H” (Accessories Diagnosis and Repair). • Explain how the body control module or body computer controls the operation of electrical accessories. • Explain how cruise control operates and how to diagnose the circuit. • Describe how power door locks, windows, and seats operate. • Describe how a keyless remote can be reprogrammed. • Explain how the theft deterrent system works.
ACCESSORY CIRCUITS
657
KEY TERMS: Adjustable pedals 670 • Backlight 662 • CHMSL 659 • Control wires 666 • Cruise control 658 • Direction wires 666 • Electric adjustable pedals (EAP) 670 • ETC 659 • HomeLink 664 • Independent switches 664 • Key fob 671 • Lockout switch 664 • Lumbar 667 • Master control switch 664 • Peltier effect 669 • Permanent magnet electric motors 664 • Rubber coupling 666 • Screw jack assembly 666 • Thermoelectric device (TED) 669 • Window regulator 664
CRUISE CONTROL PARTS INVOLVED Cruise control (also called speed control) is a combination of electrical and mechanical components designed to maintain a constant, set vehicle speed without driver pressure on the accelerator pedal. Major components of a typical cruise control system include the following: 1. Servo unit. The servo unit attaches to the throttle linkage through a cable or chain. The servo unit controls the movement of the throttle by receiving a controlled amount of vacuum from a control module. SEE FIGURE 59–1. CRUISE CONTROL SERVO UNIT
Some systems use a stepper motor and do not use engine vacuum. 2. Computer or cruise control module. This unit receives inputs from the brake switch, throttle position (TP) sensor, and vehicle speed sensor. It operates the solenoids or stepper motor to maintain the set speed. 3. Speed set control. A speed set control is a switch or control located on the steering column, steering wheel, dash, or console. Many cruise control units feature coast, accelerate, and resume functions. SEE FIGURE 59–2.
FIGURE 59–1 This cruise control servo unit has an electrical connection with wires that go to the cruise control module or the vehicle computer, depending on the vehicle. The vacuum hoses supply engine manifold vacuum to the rubber diaphragm that moves the throttle linkage to maintain the preset speed.
4. Safety release switches. When the brake pedal is depressed, the cruise control system is disengaged through use of an electrical or vacuum switch, usually located on the brake pedal bracket. Both electrical and vacuum releases are used to be certain that the cruise control system is released, even in the event of failure of one of the release switches.
CRUISE CONTROL OPERATION
A typical cruise control system can be set only if the vehicle speed is 30 mph or more. In a noncomputer-operated system, the transducer contains a lowspeed electrical switch that closes when the speed-sensing section of the transducer senses a speed exceeding the minimum engagement speed. NOTE: Toyota-built vehicles do not retain the set speed in memory if the vehicle speed drops below 25 mph (40 km/h). The driver is required to set the desired speed again. This is normal operation and not a fault with the cruise control system. When the set button is depressed on the cruise control, solenoid values on the servo unit allow engine vacuum to be applied to one side of the diaphragm, which is attached to the throttle plate of the engine through a cable or linkage. The servo unit usually contains two solenoids to control the opening and closing of the throttle.
One solenoid opens and closes to control the passage, which allows engine vacuum to be applied to the diaphragm of the servo unit, increasing the throttle opening.
One solenoid bleeds air back into the sensor chamber to reduce the throttle opening.
658
CHAPTER 59
FIGURE 59–2 A cruise control used on a Toyota/Lexus.
WARNING Most vehicle manufacturers warn in the owner manual that cruise control should not be used when it is raining or if the roads are slippery. Cruise control systems operate the throttle and, if the drive wheels start to hydroplane, the vehicle slows, causing the cruise control unit to accelerate the engine. When the engine is accelerated and the drive wheels are on a slippery road surface, vehicle stability will be lost and might possibly cause a crash.
TECH TIP
TECH TIP
Bump Problems
Check the Third Brake Light
Cruise control problem diagnosis can involve a complex series of checks and tests. The troubleshooting procedures vary among manufacturers (and year), so a technician should always consult a service manual for the exact vehicle being serviced. However, every cruise control system uses a brake safety switch and, if the vehicle has manual transmission, a clutch safety switch. The purpose of these safety switches is to ensure that the cruise control system is disabled if the brakes or the clutch is applied. Some systems use redundant brake pedal safety switches, one electrical to cut off power to the system and the other a vacuum switch used to bleed vacuum from the actuating unit. If the cruise control “cuts out” or disengages itself while traveling over bumpy roads, the most common cause is a misadjusted brake (and/or clutch) safety switch(es). Often, a simple readjustment of these safety switches will cure the intermittent cruise control disengagement problems.
On many General Motors vehicles, the cruise control will not work if the third brake light is out. This third brake light is called the center high-mounted stop light (CHMSL). Always check the brake lights first if the cruise control does not work on a General Motors vehicle.
CAUTION: Always follow the manufacturer’s recommended safety switch adjustment procedures. If the brake safety switch(es) is misadjusted, it could keep pressure applied to the master brake cylinder, resulting in severe damage to the braking system.
The throttle position (TP) sensor or a position sensor, inside the servo unit, sends the throttle position information to the cruise control module. Most computer-controlled cruise control systems use the vehicle’s speed sensor input to the engine control computer for speed reference. Computer-controlled cruise control units also use servo units for throttle control, control switches for driver control of cruise control functions, and both electrical and vacuum brake pedal release switches. SEE FIGURE 59–3.
TROUBLESHOOTING CRUISE CONTROL Cruise control system troubleshooting is usually performed using the step-by-step procedure as specified by the vehicle manufacturer. The usual steps in the diagnosis of an inoperative or incorrectly operating mechanical-type cruise control include the following: STEP 1
Use a factory or enhanced scan tool to retrieve any cruise control diagnostic trouble codes (DTCs). Perform bidirectional testing if possible using the scan tool.
STEP 2
Check that the cruise control fuse is not blown and that the cruise control dash light is on when the cruise control is turned on.
STEP 3
Check for proper operation of the brake and/or clutch switch.
STEP 4
Inspect the throttle cable and linkage between the sensor unit and the throttle plate for proper operation without binding or sticking.
STEP 5
Check the vacuum hoses for cracks or other faults.
STEP 6
Check that the vacuum servo unit (if equipped), using a handoperated vacuum pump, can hold vacuum without leaking.
STEP 7
Check the servo solenoids for proper operation, including a resistance measurement check.
ELECTRONIC THROTTLE CRUISE CONTROL PARTS AND OPERATION
Many vehicles are equipped with an electronic throttle control (ETC) system. Vehicles equipped with such a system do not use throttle actuators for the cruise control. The ETC system operates the throttle under all engine operating conditions. An ETC system uses a DC electric motor to move the throttle plate that is spring loaded to a partially open position. The motor actually closes the throttle at idle against spring pressure. The spring-loaded position is the default position and results in a high idle speed. The powertrain control module (PCM) uses the input signals from the accelerator pedal position (APP) sensor to determine the desired throttle position. The PCM then commands the throttle to the necessary position of the throttle plate. SEE FIGURE 59–4. The cruise control on a vehicle equipped with an electronic throttle control system consists of a switch to set the desired speed. The PCM receives the vehicle speed information from the vehicle speed (VS) sensor and uses the ETC system to maintain the set speed.
DIAGNOSIS AND SERVICE
Any fault in the APP sensor or ETC system will disable the cruise control function. Always follow the specified troubleshooting procedures, which will usually include the use of a scan tool to properly diagnose the ETC system.
RADAR CRUISE CONTROL PURPOSE AND FUNCTION
The purpose of a radar cruise control system is to give the driver more control over the vehicle by keeping an assured clear distance behind the vehicle in front. If the vehicle in front slows, the radar cruise control detects the slowing vehicle and automatically reduces the speed of the vehicle to keep a safe distance. Then if the vehicle speeds up, the radar cruise control also allows the vehicle to increase to the preset speed. This makes driving in congested areas easier and less tiring.
ACCESSORY CIRCUITS
659
FIGURE 59–3 Circuit diagram of a typical electronic cruise control system.
TECH TIP Use Trailer Tow Mode
FIGURE 59–4 A typical electronic throttle with the protective covers removed.
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CHAPTER 59
Some customers complain that when using cruise control while driving in hilly or mountainous areas that the speed of the vehicle will sometimes go 5 to 8 mph below the set speed. The automatic transmission then downshifts, the engine speed increases, and the vehicle returns to the set speed. To help avoid the slowdown and rapid acceleration, ask the customer to select the trailer towing position. When this mode is selected, the automatic transmission downshifts almost as soon as the vehicle speed starts to decrease. This results in a smoother operation and is less noticeable to both the driver and passengers. SEE FIGURE 59–5.
TERMINOLOGY
Depending on the manufacturer, radar cruise control is also referred to as the following:
Adaptive cruise control (Audi, Ford, General Motors, and Hyundai)
Dynamic cruise control (BMW, Toyota/Lexus)
Active cruise control (Mini Cooper, BMW)
Autonomous cruise control (Mercedes)
It uses forward-looking radar to sense the distance to the vehicle in front and maintains an assured clear distance. This type of cruise control system works within the following conditions. 1. Speeds from 20 to 100 mph (30 to 161 km/h) 2. Designed to detect objects as far away as 500 ft (150 m) The cruise control system is able to sense both distance and relative speed. SEE FIGURE 59–6.
PARTS AND OPERATION
Radar cruise control systems use long-range radar (LRR) to detect faraway objects in front of the moving vehicle. Some systems use a short-range radar (SRR) and/ or infrared (IR) or optical cameras to detect distances for when the distance between the moving vehicle and another vehicle in front is reduced. SEE FIGURE 59–7. The radar frequencies include:
76 to 77 GHz (long-range radar)
24 GHz (short-range radar)
?
FREQUENTLY ASKED QUESTION
Will Radar Cruise Control Set Off My Radar Detector? It is doubtful. The radar used for radar cruise control systems operates on frequencies that are not detectable by police radar detector units. Cruise control radar works on the following frequencies. • 76 to 77 GHz (long range) • 24 GHz (short range) The frequencies used for the various types of police radar include: • X-band: 8 to 12 GHz • K-band: 24 GHz • Ka-band: 33 to 36 GHz
FIGURE 59–5 A trailer icon lights on the dash of this Cadillac when the transmission trailer towing mode is selected.
The only time there may be interference is when the radar cruise control, as part of a precollision system, starts to use short-range radar (SRR) in the 24 GHz frequency. This would trigger the radar detector but would be an unlikely event and just before a possible collision with a vehicle coming toward you.
FIGURE 59–6 Radar cruise control uses sensors to keep the distance the same even when traffic slows ahead.
SRR
LRR
80˚
100 FEET (30 METERS) 500 FEET (150 METERS)
FIGURE 59–7 Most radar cruise control systems use radar, both long and short range. Some systems use optical or infrared cameras to detect objects.
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PRE-COLLISION SYSTEM DETECTS POSSIBLE COLLISION
ALERTS AND APPLIES BRAKES
FIGURE 59–8 A precollision system is designed to prevent a collision first, and then interacts to prepare for a collision if needed.
TO BATTERY
FUSE SWITCH L
PRECOLLISION SYSTEM
TO IGNITION
B P Y
RELAY
• OFF • NORMAL INDICATING LIGHT • ON
PURPOSE AND FUNCTION
The purpose and function of a precollision system is to monitor the road ahead and prepare to avoid a collision, and to protect the driver and passengers. A precollision system uses components of the following systems. 1. The long-range and short-range radar or detection systems used by a radar cruise control system to detect objects in front of the vehicle 2. Antilock brake system (ABS) 3. Adaptive (radar) cruise control 4. Brake assist system
TERMINOLOGY
Precollision systems can be called various names depending on the make of the vehicle. Some commonly used names for a precollision or precrash system include:
Ford/Lincoln: Collision Warning with Brake Support
Honda/Acura: Collision Mitigation Brake System (CMBS)
Mercedes-Benz: Pre-Safe or Attention Assist
Toyota/Lexus: Pre-Collision System (PCS) or Advanced PreCollision System (APCS)
General Motors: Pre-Collision System (PCS)
Volvo: Collision Warning with Brake Support or Collision Warning with Brake Assist
REAR WINDOW GRID LINE STRUCTURE
FIGURE 59–9 A switch and relay control current through the heating grid of a rear window defogger.
4. Raise the headrest (if electrically powered) 5. Pretension the seat belts 6. Airbags and seat belt tensioners function as designed during the collision
HEATED REAR WINDOW DEFOGGERS PARTS AND OPERATION
OPERATION
The system functions by monitoring objects in front of the vehicle and can act to avoid a collision by the following actions.
Sounds an alarm
Flashes a warning lamp
Applies the brakes and brings the vehicle to a full stop (if needed), if the driver does not react
SEE FIGURE 59–8. If the system is unable to prevent a collision, the system will perform the following actions. 1. Apply the brakes full force to reduce vehicle speed as much as possible 2. Close all windows and the sunroof to prevent the occupants from being ejected from the vehicle 3. Move the seats to an upright position
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An electrically heated rear window defogger system uses an electrical grid baked on the glass that warms the glass to about 85°F (29°C) and clears it of fog or frost. The rear window is also called a backlight. The rear window defogger system is controlled by a driver-operated switch and a timer relay. SEE FIGURE 59–9. The timer relay is necessary because the window grid can draw up to 30 A, and continued operation would put a strain on the battery and the charging system. Generally, the timer relay permits current to flow through the rear window grid for only 10 minutes. If the window is still not clear of fog after 10 minutes, the driver can turn the defogger on again, but after the first 10 minutes any additional defogger operation is limited to 5 minutes.
PRECAUTION
Electric grid-type rear window defoggers can be damaged easily by careless cleaning or scraping of the inside of the rear window glass. Short, broken sections of the rear window grid can be repaired using a special epoxy-based electrically conductive
VOLTMETER 12.53
MASKING TAPE
GROUND SIDE HEATING ELEMENTS OF A REAR WINDOW DEFOGGER
POWER FEED SIDE
FIGURE 59–10 A rear window defogger electrical grid can be tested using a voltmeter to check for a decreasing voltage as the meter lead is moved from the power side toward the ground side. As the voltmeter positive lead is moved along the grid (on the inside of the vehicle), the voltmeter reading should steadily decrease as the meter approaches the ground side of the grid.
material. If more than one section is damaged or if the damaged grid length is greater than approximately 1.5 in. (3.8 cm), a replacement rear window glass may be required to restore proper defogger operation. The electrical current through the grids depends, in part, on the temperature of the conductor grids. As the temperature decreases, the resistance of the grids decreases and the current flow increases, helping to warm the rear glass. As the temperature of the glass increases, the resistance of the conductor grids increases and the current flow decreases. Therefore, the defogger system tends to self-regulate the electrical current requirements to match the need for defogging. NOTE: Some vehicles use the wire grid of the rear window defogger as the radio antenna. Therefore, if the grid is damaged, radio reception can also be affected.
HEATED REAR WINDOW DEFOGGER DIAGNOSIS
Troubleshooting a nonfunctioning rear window defogger unit involves using a test light or a voltmeter to check for voltage to the grid. If no voltage is present at the rear window, check for voltage at the switch and relay timer assembly. A poor ground connection on the opposite side of the grid from the power side can also cause the rear defogger not to operate. Because most defogger circuits use an indicator light switch and a relay timer, it is possible to have the indicator light on, even if the wires are disconnected at the rear window grid. A voltmeter can be used to test the operation of the rear window defogger grid. SEE FIGURE 59–10. With the negative test terminal attached to a good body ground, carefully probe the grid conductors. There should be a decreasing voltage reading as the probe is moved from the power (“hot”) side of the grid toward the ground side of the grid.
REPAIR OR REPLACEMENT
If there is a broken grid wire, it can be repaired using an electrically conductive substance available in a repair kit.
FIGURE 59–11 The typical repair material contains conductive silver-filled polymer, which dries in 10 minutes and is usable in 30 minutes.
TECH TIP The Breath Test It is difficult to test for the proper operation of all grids of a rear window defogger unless the rear window happens to be covered with fog. A common trick that works is to turn on the rear defogger and exhale onto the outside of the rear window glass. In a manner similar to that of people cleaning eyeglasses with their breath, this procedure produces a temporary fog on the glass so that all sections of the rear grids can quickly be checked for proper operation.
Most vehicle manufacturers recommend that grid wire less than 2 in. (5 cm) long be repaired. If a bad section is longer than 2 in., the entire rear window will need to be replaced. SEE FIGURE 59–11.
HEATED MIRRORS PURPOSE AND FUNCTION
The purpose and function of heated outside mirrors is to heat the surface of the mirror, which evaporates moisture on the surface. The heat helps keep ice and fog off the mirrors, to allow for better driver visibility.
PARTS AND OPERATION
Heated outside mirrors are often tied into the same electrical circuit as the rear window defogger. Therefore, when the rear defogger is turned on, the heating grid on the backside of the mirror is also turned on. Some vehicles use a switch for each mirror.
DIAGNOSIS The first step in any diagnosis procedure is to verify the customer concern. Check the owner’s manual or service information for the proper method to use to turn on the heated mirrors. NOTE: Heated mirrors are not designed to melt snow or a thick layer of ice. If a fault has been detected, follow service information instructions for the exact procedure to follow. If the mirror itself is found to be defective, it is usually replaced as an assembly instead of being repaired.
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FIGURE 59–12 Typical HomeLink garage door opener buttons. Notice that three different units can be controlled from the vehicle using the HomeLink system.
HOMELINK GARAGE DOOR OPENER OPERATION
HomeLink is a device installed in many new vehicles that duplicates the radio-frequency code of the original garage door opener. The frequency range which HomeLink is able to operate is 288 to 418 MHz. The typical vehicle garage door opening system has three buttons that can be used to operate one or more of the following devices. 1. Garage doors equipped with a radio transmitter electric opener 2. Gates 3. Entry door locks 4. Lighting or small appliances
The devices include both fixed-frequency devices, usually older units, and rolling (encrypted) code devices. SEE FIGURE 59–12.
PROGRAMMING A VEHICLE GARAGE DOOR OPENER When a vehicle is purchased, it must be programmed using the transmitter for the garage door opener or other device. NOTE: The HomeLink garage door opening controller can only be programmed by using a transmitter. If an automatic garage door system does not have a remote transmitter, HomeLink cannot be programmed. Normally, the customer is responsible for programming the HomeLink to the garage door opener. However, some customers may find that help is needed from the service department. The steps that are usually involved in programming HomeLink in the vehicle to the garage door opener are as follows: STEP 1
Unplug the garage door opener during programming to prevent it from being cycled on and off, which could damage the motor.
STEP 2
Check that the frequency of the handheld transmitter is between 288 and 418 MHz.
STEP 3
Install new batteries in the transmitter to be assured of a strong signal being transmitted to the HomeLink module in the vehicle.
STEP 4
Turn the ignition on, engine off (KOEO).
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STEP 5
While holding the transmitter 4 to 6 in. away from the HomeLink button, press and hold the HomeLink button while pressing and releasing the handheld transmitter every two seconds. Continue pressing and releasing the transmitter until the indicator light near the HomeLink button changes from slow blink to a rapid flash.
STEP 6
Verify that the vehicle garage door system (HomeLink) button has been programmed. Press and hold the garage door button. If the indicator light blinks rapidly for two seconds and then comes on steady, the system has been successfully programmed using a rolling code design. If the indicator light is on steady, then it has been successfully programmed to a fixed-frequency device.
DIAGNOSIS AND SERVICE
If a fault occurs with the HomeLink system, first verify that the garage door opener is functioning correctly. Also, check if the garage door opener remote control is capable of operating the door. Repair the garage door opener system as needed. If the problem still exists, attempt reprogramming the HomeLink vehicle system, being sure that the remote has a newly purchased battery.
POWER WINDOWS SWITCHES AND CONTROLS
Power windows use electric motors to raise and lower door glass. They can be operated by both a master control switch located beside the driver and additional independent switches for each electric window. Some power window systems use a lockout switch located on the driver’s controls to prevent operation of the power windows from the independent switches. Power windows are designed to operate only with the ignition switch in the on (run) position, although some manufacturers use a time delay for accessory power after the ignition switch is turned off. This feature permits the driver and passengers an opportunity to close all windows or operate other accessories for about 10 minutes or until a vehicle door is opened after the ignition has been turned off. This feature is often called retained accessory power.
POWER WINDOW MOTORS
Most power window systems use permanent magnet (PM) electric motors. It is possible to run a PM motor in the reverse direction simply by reversing the polarity of the two wires going to the motor. Most power window motors do not require that the motor be grounded to the body (door) of the vehicle. The ground for all the power windows is most often centralized near the driver’s master control switch. The up-and-down motion of the individual window motors is controlled by double-pole, doublethrow (DPDT) switches. These DPDT switches have five contacts and permit battery voltage to be applied to the power window motor, as well as reverse the polarity and direction of the motor. Each motor is protected by an electronic circuit breaker. These circuit breakers are built into the motor assembly and are not a separate replaceable part. SEE FIGURE 59–13. The power window motors rotate a mechanism called a window regulator. The window regulator is attached to the door glass and controls opening and closing of the glass. Door glass adjustments such as glass tilt and upper and lower stops are usually the same for both power and manual windows. SEE FIGURE 59–14.
HOT IN RUN 30-A CIRCUIT BREAKER
FUSE PANEL POWER (BAT )
UP
DOWN
UP
DOWN
B GROUND
MASTER CONTROL SWITCH
THIS IS THE ONLY GROUND CONNECTION FOR ALL OF THE POWER WINDOWS CIRCUIT BREAKERS BUILT INTO MOTOR HOUSING
RIGHT FRONT WINDOW SWITCH INDEPENDENT SWITCH)
RIGHT FRONT WINDOW MOTOR
LEFT FRONT WINDOW MOTOR
PERMANENTMAGNET REVERSIBLE MOTORS
FIGURE 59–13 A typical power window circuit using PM motors. Control of the direction of window operation is achieved by directing the polarity of the current through the nongrounded motors. The only ground for the entire system is located at the master control (driver’s side) switch assembly.
AUTO DOWN/UP FEATURES
GLASS
MOTOR
GLASS GUIDE GLASS GUIDE
REGULATOR ASSEMBLY
FIGURE 59–14 An electric motor and a regulator assembly raise and lower the glass on a power window.
Many power windows are equipped with an auto down feature that allows windows to be lowered all of the way if the control switch is moved to a detent or held down for longer than 0.3 second. The window will then move down all the way to the bottom, and then the motor stops. Many vehicles are equipped with the auto up feature that allows the driver to raise the driver’s side or all windows in some cases, with just one push of the button. A sensor in the window motor circuit measures the current through the motor. The circuit is opened if the window touches an object, such as a hand or finger. When the window reaches the top or hits an object, the current through the window motor increases. When the upper limit amperage draw is reached, the motor circuit is opened and the window either stops or reverses. Most newer power windows use network communications modules to operate the power windows, and the switches are simply voltage signals to the module which supplies current to the individual window motors. SEE FIGURE 59–15.
TROUBLESHOOTING POWER WINDOWS
Before troubleshooting a power window problem, check for proper operation of all power windows. Check service information for the exact procedure
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ELECTRIC MOTORS CABLES
FIGURE 59–15 A master power window control panel with the buttons and the cover removed.
TECH TIP Programming Auto Down Power Windows Many vehicles are equipped with automatic operation that can cause the window to go all the way down (or up) if the switch is depressed beyond a certain point or held for a fraction of a second. Sometimes this feature is lost if the battery in the vehicle has been disconnected. Although this programming procedure can vary depending on the make and model, many times the window(s) can be reprogrammed without using a scan tool by simply depressing and holding the down button for 10 seconds. If the vehicle is equipped with an auto up feature, repeat the procedure by holding the button up for 10 seconds. Always check service information for the vehicle being serviced.
to follow. In a newer system, a scan tool can be used to perform the following:
Check for B (body) or U (network) diagnostic trouble codes (DTCs)
Operate the power windows using the bidirectional control feature
Relearn or program the operation of the power windows after a battery disconnect
For older systems, if one of the control wires that run from the independent switch to the master switch is cut (open), the power window may operate in only one direction. The window may go down but not up, or vice versa. However, if one of the direction wires that run from the independent switch to the motor is cut (open), the window will not operate in either direction. The direction wires and the motor must be electrically connected to permit operation and change of direction of the electric lift motor in the door. 1. If both rear door windows fail to operate from the independent switches, check the operation of the window lockout (if the vehicle is so equipped) and the master control switch. 2. If one window can move in one direction only, check for continuity in the control wires (wires between the independent control switch and the master control switch). 3. If all windows fail to work or fail to work occasionally, check, clean, and tighten the ground wire(s) located either behind the
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FIGURE 59–16 A power seat uses electric motors under the seat, which drive cables that extend to operate screw jacks (up and down) or gears to move the seat forward and back.
driver’s interior door panel or under the dash on the driver’s side. A defective fuse or circuit breaker could also cause all the windows to fail to operate. 4. If one window fails to operate in both directions, the problem could be a defective window lift motor. The window could be stuck in the track of the door, which could cause the circuit breaker built into the motor to open the circuit to protect the wiring, switches, and motor from damage. To check for a stuck door glass, attempt to move (even slightly) the door glass up and down, forward and back, and side to side. If the window glass can move slightly in all directions, the power window motor should be able to at least move the glass. 5. Always refer to and follow service information when diagnosing power window circuits.
POWER SEATS PARTS AND OPERATION
A typical power-operated seat includes a reversible electric motor and a transmission assembly that may have three solenoids and six drive cables that turn the six seat adjusters. A six-way power seat offers seat movement forward and backward, plus seat cushion movement up and down at the front and the rear. The drive cables are similar to speedometer cables because they rotate inside a cable housing and connect the power output of the seat transmission to a gear or screw jack assembly that moves the seat. SEE FIGURE 59–16. A screw jack assembly is often called a gear nut. It is used to move the front or back of the seat cushion up and down. A rubber coupling, usually located between the electric motor and the transmission, and prevents electric motor damage in the event of a jammed seat. This coupling is designed to prevent motor damage. Most power seats use a permanent magnet motor that can be reversed by simply reversing the polarity of the current sent to the motor by the seat switch. SEE FIGURE 59–17.
HOT AT ALL TIMES
SEAT CB FUSE 25 A BLOCK
FORWARD/REARWARD BACK
FWD
FRONT
REAR
UP
DOWN
PTC
PTC
M POSITION MOTOR
DOWN
UP
PTC
M
M
FRONT TILT MOTOR
REAR TILT MOTOR
FIGURE 59–17 A typical power seat circuit diagram. Notice that each motor has a built-in electronic (solid-state) PTC circuit protector. The seat control switch can change the direction in which the motor(s) runs by reversing the direction in which the current flows through the motor.
POWER SEAT MOTOR(S)
Most PM motors have a built-in circuit breaker or PTC circuit protector to protect the motor from overheating. Many Ford power seat motors use three separate armatures inside one large permanent magnet field housing. Some power seats use a series-wound electric motor with two separate field coils, one field coil for each direction of rotation. This type of power seat motor typically uses a relay to control the direction of current from the seat switch to the corresponding field coil of the seat motor. This type of power seat can be identified by the “click” heard when the seat switch is changed from up to down or front to back, or vice versa. The click is the sound of the relay switching the field coil current. Some power seats use as many as eight separate PM motors that operate all functions of the seat, including headrest height, seat length, and side bolsters, in addition to the usual sixway power seat functions. NOTE: Some power seats use a small air pump to inflate a bag (or bags) in the lower part of the back of the seat, called the lumbar, because it supports the lumbar section of the spine. The lumbar section of the seat can also be changed, using a lever or knob that the driver can move to change the seat section for the lower back.
MEMORY SEAT
Memory seats use a potentiometer to sense the position of the seat. The seat position can be programmed into the body control module (BCM) or memory seat module and stored by position number 1, 2, or 3. The driver pushes the desired button and the seat moves to the stored position. SEE FIGURE 59–18 on page 668.
TECH TIP Easy Exit Seat Programming Some vehicles are equipped with memory seats that allow the seat to move rearward when the ignition is turned off to allow easy exit from the vehicle. Vehicles equipped with this feature include an exit/entry button that is used to program the desired exit/entry position of the seat for each of two drivers. If the vehicle is not equipped with this feature and only one driver primarily uses the vehicle, the second memory position can be programmed for easy exit and entry. Simply set position 1 to the desired seat position and position 2 to the entry/exit position. Then, when exiting the vehicle, press memory 2 to allow easy exit and easy entry the next time. Press memory 1 when in the vehicle to return the seat memory to the desired driving position.
On some vehicles, the memory seat position is also programmed into the remote keyless entry key fob.
TROUBLESHOOTING POWER SEATS
Power seats are usually wired from the fuse panel so they can be operated without having to turn the ignition switch to on (run). If a power seat does not
ACCESSORY CIRCUITS
667
HOT AT ALL TIMES
HORIZONTAL MOTOR CONTROL
HORIZONTAL MOTOR
FRONT VERTICAL MOTOR CONTROL
REAR VERTICAL MOTOR CONTROL
VERTICAL MOTOR
VERTICAL MOTOR PTC
PTC
PTC
M
M
M
5V
5V
HORIZONTAL POSITION SIGNAL
LH SEAT CONTROL MODULE
POSITION SENSOR GROUND
5V
VERTICAL POSITION SIGNAL
5V
LH SEAT CONTROL MODULE
VERTICAL POSITION SIGNAL
FIGURE 59–18 A typical memory seat module showing the three-wire potentiometer used to determine seat position.
TECH TIP What Every Driver Should Know About Power Seats Power seats use an electric motor or motors to move the position of the seat. These electric motors turn small cables that operate mechanisms that move the seat. Never place rags, newspapers, or any other object under a power seat. Even ice scrapers can get caught between moving parts of the seat and can often cause serious damage or jamming of the power seat.
operate or make any noise, the circuit breaker (or fuse, if the vehicle is so equipped) should be checked first. The steps usually include: STEP 1
Check service information for the exact procedure to follow when diagnosing power seats. If the seat relay clicks, the circuit breaker is functioning, but the relay or electric motor may be defective.
STEP 2
Remove the screws or clips that retain the controls to the inner door panel or seat and check for voltage at the seat control.
STEP 3
Check the ground connection(s) at the transmission and clutch control solenoids (if equipped). The solenoids must be properly grounded to the vehicle body for the power seat circuit to operate.
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If the power seat motor runs but does not move the seat, the most likely fault is a worn or defective rubber clutch sleeve between the electric seat motor and the transmission. If the seat relay clicks but the seat motor does not operate, the problem is usually a defective seat motor or defective wiring between the motor and the relay. If the power seat uses a motor relay, the motor has a double reverse-wound field for reversing the motor direction. This type of electric motor must be properly grounded. Permanent magnet motors do not require grounding for operation. NOTE: Power seats are often difficult to service because of restricted working room. If the entire seat cannot be removed from the vehicle because the track bolts are covered, attempt to remove the seat from the top of the power seat assembly. These bolts are almost always accessible regardless of seat position.
ELECTRICALLY HEATED SEATS PARTS AND OPERATION
Heated seats use electric heating elements in the seat bottom, as well as in the seat back in many vehicles. The heating element is designed to warm the seat and/or back of the seat to about 100°F (37°C) or close to normal
COOLED SURFACE P
N
DISSIPATED HEAT
FIGURE 59–20 A Peltier effect device is capable of heating or cooling, depending on the polarity of the applied current. FIGURE 59–19 The heating element of a heated seat is a replaceable part, but service requires that the upholstery be removed. The yellow part is the seat foam material and the entire white cover is the replaceable heating element. This is then covered by the seat material. body temperature (98.6°F). Many heated seats also include a highposition or a variable temperature setting, so the temperature of the seats can therefore be as high as 110°F (44°C). A temperature sensor in the seat cushion is used to regulate the temperature. The sensor is a variable resistor which changes with temperature and is used as an input signal to a heated seat control module. The heated seat module uses the seat temperature input, as well as the input from the high-low (or variable) temperature control, to turn the current on or off to the heating element in the seat. Some vehicles are equipped with heated seats in both the rear and the front seats.
DIAGNOSIS AND SERVICE
When diagnosing a heated seat concern, start by verifying that the switch is in the on position and that the temperature of the seat is below normal body temperature. Using service information, check for power and ground at the control module and to the heating element in the seat. Most vehicle manufacturers recommend replacing the entire heating element if it is defective. SEE FIGURE 59–19.
HEATED AND COOLED SEATS
TECH TIP Check the Seat Filter Heated and cooled seats often use a filter to trap dirt and debris to help keep the air passages clean. If a customer complains of a slow heating or cooling of the seat, check the air filter and replace or clean as necessary. Check service information for the exact location of the seat filter and for instructions on how to remove and/or replace it.
and seat back. Each thermoelectric device has a temperature sensor, called a thermistor. The control module uses sensors to determine the temperature of the fins in the thermoelectric device so the controller can maintain the set temperature.
DIAGNOSIS AND SERVICE
The first step in any diagnosis is to verify that the heated-cooled seat system is not functioning. Check the owner’s manual or service information for the specified procedures. If the system works partially, check the air filter, usually located under the seat for each thermoelectric device. A partially clogged filter can restrict airflow and reduce the heating or cooling effect. If the system control indicator light is not on or the system does not work at all, check for power and ground at the thermoelectric devices. Always follow the vehicle manufacturer’s recommended diagnosis and service procedures.
PARTS AND OPERATION
Most electrically heated and cooled seats use a thermoelectric device (TED) located under the seat cushion and seat back. The thermoelectric device consists of positive and negative connections between two ceramic plates. Each ceramic plate has copper fins to allow the transfer of heat to air passing over the device and directed into the seat cushion. The thermoelectric device uses the Peltier effect, named after the inventor, Jean C. A. Peltier, a French clockmaker. When electrical current flows through the module, one side is heated and the other side is cooled. Reversing the polarity of the current changes which side is heated. SEE FIGURE 59–20. Most vehicles equipped with heated and cooled seats use two modules per seat, one for the seat cushion and one for the seat back. When the heated and cooled seats are turned on, air is forced through a filter and then through the thermoelectric modules. The air is then directed through passages in the foam of the seat cushion
HEATED STEERING WHEEL PARTS INVOLVED
A heated steering wheel usually consists of the following components.
Steering wheel with a built-in heater in the rim
Heated steering wheel control switch
Heated steering wheel control module
OPERATION
When the steering wheel heater control switch is turned on, a signal is sent to the control module and electrical current flows through the heating element in the rim of the steering wheel. SEE FIGURE 59–21. ACCESSORY CIRCUITS
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ADJUSTABLE PEDAL MOTOR
CABLE
STEERING WHEEL ICON
ADJUSTABLE PEDAL BRACKET
FIGURE 59–21 The heated steering wheel is controlled by a switch on the steering wheel in this vehicle.
The system remains on until the ignition switch is turned off or the driver turns off the control switch. The temperature of the steering wheel is usually calibrated to stay at about 90°F (32°C), and it requires three to four minutes to reach that temperature depending on the outside temperature.
DIAGNOSIS AND SERVICE
BRAKE PEDAL
ACCELERATOR PEDAL
FIGURE 59–22 A typical adjustable pedal assembly. Both the accelerator and the brake pedal can be moved forward and rearward by using the adjustable pedal position switch.
Diagnosis of a heated steering wheel starts with verifying that the heated steering wheel is not working as designed. NOTE: Most heated steering wheels do not work if the temperature inside the vehicle is about 90°F (32°C) or higher.
TECH TIP Check the Remote
If the heated steering wheel is not working, follow the service information testing procedures which would include a check of the following: 1. Check the heated steering wheel control switch for proper operation. This is usually done by checking for voltage at both terminals of the switch. If voltage is available at only one of the two terminals of the switch and the switch has been turned on and off, an open (defective) switch is indicated. 2. Check for voltage and ground at the terminals leading to the heating element. If voltage is available at the heating element and the ground has less than 0.2 volt drop to a good chassis ground, the heating element is defective. The entire steering wheel has to be replaced if the element is defective. Always follow the vehicle manufacturer’s recommended diagnosis and testing procedures.
ADJUSTABLE PEDALS
The memory function may be programmed to a particular key fob remote, which would command the adjustable pedals to move to the position set in memory. Always check both remote settings before attempting to repair a problem that may not be a problem.
The position of the pedals, as well as the position of the seat system, is usually included as part of the memory seat function and can be set for two or more drivers.
DIAGNOSIS AND SERVICE
The first step when there is a customer concern about the functioning of the adjustable pedals is to verify that the unit is not working as designed. Check the owner manual or service information for the proper operation. Follow the vehicle manufacturer’s recommended troubleshooting procedure. Many diagnostic procedures include the use of a factory scan tool with bidirectional control capabilities to test this system.
PURPOSE AND FUNCTION
Adjustable pedals, also called electric adjustable pedals (EAP), place the brake pedal and the accelerator pedal on movable brackets that are motor operated. A typical adjustable pedal system includes the following components.
Adjustable pedal position switch. Allows the driver to position the pedals
Adjustable pedal assembly. Includes the motor, threaded adjustment rods, and a pedal position sensor
SEE FIGURE 59–22.
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OUTSIDE FOLDING MIRRORS Mirrors that can be electrically folded inward are a popular feature, especially on larger sport utility vehicles. A control inside is used to fold both mirrors inward when needed, such as when entering a garage or close parking spot. For diagnosis and servicing of outside folding mirrors, check service information for details.
CONTROL CIRCUIT
POWER CIRCUIT
HOT AT ALL TIMES
HOT AT ALL TIMES 30 A CIRCUIT BREAKER
20 A FUSE
LEFT DOOR LOCK SWITCH
RIGHT DOOR LOCK SWITCH
LOCK UNLOCK
LOCK
UNLOCK
FIGURE 59–23 Electrically folded mirror in the folded position. LOCK
UNLOCK
DOOR LOCK RELAY
UNLOCK
LEFT DOOR LOCK MOTOR
M
M
RIGHT DOOR LOCK MOTOR
LOCK
FIGURE 59–24 The electric mirror control is located on the driver’s side door panel on this Cadillac Escalade. REAL WORLD FIX The Case of the Haunted Mirrors The owner complained that while driving, either one or the other outside mirror would fold in without any button being depressed. Unable to verify the customer concern, the service technician looked at the owner’s manual to find out exactly how the mirrors were supposed to work. In the manual, a caution statement said that if the mirror is electrically folded inward and then manually pushed out, the mirror will not lock into position. The power folding mirrors must be electrically cycled outward, using the mirror switches to lock them in position. After cycling both mirrors inward and outward electrically, the problem was solved. SEE FIGURES 59–23 AND 59–24.
FIGURE 59–25 A typical electric power door lock circuit diagram. Note that the control circuit is protected by a fuse, whereas the power circuit is protected by a circuit breaker. As with the operation of power windows, power door locks typically use reversible permanent magnet (PM) nongrounded electric motors. These motors are geared mechanically to the lock-unlock mechanism.
The electric motor uses a built-in circuit breaker and operates the lock-activating rod. PM reversible motors do not require grounding because, as with power windows, the motor control is determined by the polarity of the current through the two motor wires. SEE FIGURE 59–25. Some two-door vehicles do not use a power door lock relay because the current flow for only two PM motors can be handled through the door lock switches. However, most four-door vehicles and vans with power locks on rear and side doors use a relay to control the current flow necessary to operate four or more power door lock motors. The door lock relay is controlled by the door lock switch and is commonly the location of the one and only ground connection for the entire door lock circuit.
KEYLESS ENTRY ELECTRIC POWER DOOR LOCKS Electric power door locks use a permanent magnet (PM) reversible motor to lock or unlock all vehicle door locks from a control switch or switches.
Even though some Ford vehicles use a keypad located on the outside of the door, most keyless entry systems use a wireless transmitter built into the key or key fob. A key fob is a decorative tab or item on a key chain. SEE FIGURE 59–26. The transmitter broadcasts a signal that is received by the electronic control module, which is generally mounted in the trunk or under the instrument panel. SEE FIGURE 59–27.
ACCESSORY CIRCUITS
671
The electronic control unit sends a voltage signal to the door lock actuator(s) located in the doors. Generally, if the transmitter unlock button is depressed once, only the driver’s door is unlocked. If the unlock button is depressed twice, then all doors unlock.
ROLLING CODE RESET PROCEDURE
Many keyless remote systems use a rolling code type of transmitter and receiver. In a conventional system, the transmitter emits a certain fixed frequency, which is received by the vehicle control module. This single frequency can be intercepted and rebroadcast to open the vehicle. A rolling code type of transmitter emits a different frequency every time the transmitter button is depressed and then rolls over to
another frequency so that it cannot be intercepted. Both the transmitter and the receiver must be kept in synchronized order so that the remote will function correctly. If the transmitter is depressed when it is out of range from the vehicle, the proper frequency may not be recognized by the receiver, which did not roll over to the new frequency when the transmitter was depressed. If the transmitter does not work, try to resynchronize the transmitter to the receiver by depressing and holding both the lock and the unlock button for 10 seconds when within range of the receiver.
KEYLESS ENTRY DIAGNOSIS
A small battery powers the transmitter, and a weak battery is a common cause of remote power locks failing to operate. If the keyless entry system fails to operate after the transmitter battery has been replaced, check the following items.
Mechanical binding in the door lock
Low vehicle battery voltage
Blown fuse
Open circuit to the control module
Defective control module
Defective transmitter
PROGRAMMING A NEW REMOTE FIGURE 59–26 A key fob remote with the cover removed showing the replaceable battery.
If a new or additional remote transmitter is to be used, it must be programmed to the vehicle. The programming procedure varies and may require the use of a scan tool. Check service information for the exact procedure to follow. SEE CHART 59–1.
FRONT PASSENGER’S KEY CYLINDER SWITCH FRONT PASSENGER DOOR LOCK KEYLESS ACTUATOR/KNOB SWITCH RECEIVER UNIT IGNITION KEY SWITCH DRIVER’S DOOR LOCK SWITCH
FRONT PASSENGER’S DOOR SWITCH RIGHT REAR DOOR LOCK ACTUATOR/KNOB SWITCH RIGHT REAR DOOR SWITCH
DRIVER’S DOOR KEY CYLINDER SWITCH
DRIVER’S DOOR LOCK ACTUATOR/KNOB SWITCH DRIVER’S DOOR SWITCH LEFT REAR DOOR LOCK ACTUATOR/KNOB SWITCH
TRUNK KEY CYLINDER SWITCH LEFT REAR DOOR SWITCH
TRUNK LATCH SWITCH
FIGURE 59–27 A typical vehicle showing the location of the various components of the remote keyless entry system.
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PROCEDURE
Acura RSX MDX 3.2TL RSX
Be careful to maintain the time limits between steps.
1. 2. 3. 4. 5. 6. 7. 8.
Honda Accord Civic CR-V Odyssey
Ensure that the hood, tailgate, and doors are closed. Aim the transmitter at the receiver in the power window master switch. The keyless receiver can store up to three codes. If a fourth code is stored, the first code that was input will be erased.
BMW All models with transmitter in key head
Up to four transmitters can be programmed.
Buick Rendezvous Lucerne LaCrosse
A scan tool is required.
Chevrolet Blazer Impala Monte Carlo Uplander
All transmitters to be programmed must be programmed at the same time. This procedure erases all learned transmitters.
A total of four transmitters can be learned. All transmitters to be programmed must be programmed at the same time. Activating program mode erases previously learned codes.
Turn the ignition on. Within 1 to 4 seconds, press the lock or unlock button. Within 1 to 4 seconds, turn the ignition off. Repeat steps 1 through 3 two more times. Within 1 to 4 seconds, turn the ignition on (fourth time). Within 1 to 4 seconds, press the lock or unlock button. The door lock actuators should cycle. Press the lock or unlock button a second time within 1 to 4 seconds to store the code. 9. For additional transmitters, repeat steps 6, 7, and 8. 10. Turn the ignition off and remove the key to exit programming mode. 1. Use the vehicle key to unlock the central locking system. 2. Enter the vehicle and close all doors. 3. Put the key in the ignition and switch the ignition switch to position 1 and then back to off, within 5 seconds. 4. Press and hold key button 2 (arrow button). 5. While holding button 2, press button 1 (BMW logo) three times within 10 seconds. 6. Release button 2. 7. The locks will cycle to confirm programming. 8. Repeat steps 4 through 7 within 30 seconds for any additional transmitters. 9. After 30 seconds with no button pressed the programming mode will exit. 1. Install a scan tool and access the BCM Special Functions, Lift Gate Module (LGM), or Module Setup; Program Key Fobs menu. 2. Press the start key on the scan tool. 3. Press and hold both the lock and unlock buttons on the first transmitter. Within 5 to 10 seconds the scan tool will report that the transmitter is programmed. 4. Repeat step 3 to program up to four transmitters. 5. Turn off and remove the scan tool to exit programming mode.
Pontiac Grand Prix Montana Saturn Relay Buick Rainier
Fobs can also be programmed with a scan tool.
Cadillac Escalade
All fobs to be used must be programmed at the same time.
Chevrolet C/K Trucks Suburban Tahoe Trailblazer
The first fob learned will be fob 1 and the second that is learned will be fob 2.
1. Enter the vehicle and close all the doors. 2. Insert the key into the ignition lock. 3. Press and hold the door unlock switch, then turn the ignition on, off, then release the unlock switch. 4. The door locks will cycle one time to confirm programming mode. 5. Press and hold the lock and unlock buttons on the key fob for about 15 seconds. 6. The locks will cycle once when the fob has been learned. 7. Repeat steps 5 and 6 to program any additional fobs. 8. Turn the ignition key to run, to exit the programming mode.
Saab 9-7 (some) CHART 59–1
(CONTINUED)
Remote keyless programming steps for popular vehicles. Procedures may also apply to similar vehicles by the same manufacturer. Always refer to service information for specific vehicles.
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Cadillac CTS SRX
All programmed key fobs will be erased. All transmitters to be programmed must be relearned during this procedure.
1. Install the scan tool and turn the ignition on. 2. Navigate to the Body, RFA (or RCDLR), Special Functions; Program Key Fobs menu. 3. Follow the directions on the scan tool to program the transmitters.
Up to four fobs can be programmed. The first to be learned will be fob 1 and the second to be learned will be fob 2. Cadillac Deville Seville Pontiac Bonneville Grand Am
Cadillac STS XLR Chevrolet Corvette
Up to four transmitters can be programmed. All fobs to be used must be programmed at the same time. The first fob learned will be fob 1 and the second that is learned will be fob 2. A scan tool can also be used to program key fobs. This procedure will take 30 minutes to complete. All programmed key fobs will be erased. All transmitters to be programmed must be relearned during this procedure. Up to four fobs can be programmed. The first to be learned will be fob 1 and the second to be learned will be fob 2.
Chevrolet Cavalier Equinox Malibu SSR S/T Trucks Saab 9–7 (some models)
A scan tool is required. Up to four transmitters can be programmed. On vehicles with personalization features, the transmitters are numbered 1 and 2. The first transmitter programmed will become driver 1 and the second will become driver 2.
1. Install a scan tool and turn on the ignition. 2. Navigate to the Remote Function Actuator (RFA) module: Special function, Program Key Fobs menu to activate program mode. 3. The doors will lock and unlock to indicate programming mode. 4. Press and hold the lock and unlock buttons on the fob. The door locks will cycle to indicate the fob has been learned. 5. Repeat step 4 for any additional fobs. 6. To exit programming mode, turn off and remove the scan tool. 1. Start with the vehicle off. 2. Place the fob to be learned in the console pocket with the buttons facing forward. 3. Insert the vehicle key into the driver’s door lock cylinder and cycle the key five times within 5 seconds. The DIC will display “OFF/ACC TO LEARN.” 4. Press the OFF/ACC part of the ignition button. 5. The DIC will display “WAIT 10 MINUTES,” then count down to zero, 1 minute at a time. The display will change to “OFF/ACC TO LEARN.” 6. Repeat steps 4 and 5 two more times for a total of 30 minutes. 7. When the DIC displays “OFF/ACC TO LEARN” for the fourth time, press the OFF/ACC button again; the DIC will display “READY FOR FOB 1.” 8. When fob 1 has been learned, a beep will be heard and the DIC will display “READY FOR FOB 2.” 9. Remove fob 1 from the pocket and insert fob 2. A beep will be heard when that fob has been learned. 10. Repeat steps 8 and 9 for additional fobs. 11. To exit programming, press the OFF/ACC portion of the ignition button. 1. Install the scan tool and navigate to the BCM or RFA menu, Special Functions; select Program Key Fobs. 2. Select Add/Replace Key Fob to program a new or additional fob. 3. Select Clear Memory and Program All Fobs option to replace all fobs or to recode driver 1 and driver 2 fobs. 4. Follow the scan tool instructions to complete the programming.
Saturn Vue Chevrolet Venture van GM “U” vans
All fobs to be used must be programmed at the same time. Up to four transmitters can be programmed. If the BCM displays DTCs in step 5, they may have to be resolved before programming can continue.
1. With the ignition key out of the ignition, remove the BCM PRGRM fuse from the passenger side fuse block. 2. Enter the vehicle and close all doors. 3. Insert the key and turn the ignition to ACC. 4. The seat belt indicator and chime will activate two, three, or four times, depending on the type of BCM in the vehicle. 5. Turn the key off and then back to ACC within 1 second. If the BCM has any stored DTCs, they will be displayed by the chime and belt indicator at this time. 6. Open and close any door. The chime will sound to indicate programming mode. 7. Press and hold the fob lock and unlock buttons for about 14 seconds. The BCM will sound the chime when the fob has been learned. 8. Repeat step 7 for up to four total transmitters. 9. After programming, remove the ignition key and replace the BCM PRGRM fuse.
CHART 59–1 Remote keyless programming steps for popular vehicles. Procedures may also apply to similar vehicles by the same manufacturer. Always refer to service information for specific vehicles.
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Chrysler PT Cruiser Concorde
A scan tool is required if there are no functioning transmitters.
1. Turn ignition to run and wait until the chimes stop or fasten seat belt to cancel chimes. 2. Using any original working transmitter, press and hold the unlock button for 4 to 10 seconds. 3. While holding the unlock button, press the panic button for 1 second. Chime will sound to indicate programming mode is ready. 4. Press and release any button on the transmitters to be programmed. All transmitters should be programmed at this time, including previously programmed transmitters. A chime will sound after each programming success. 5. Turn the ignition off to exit programming.
Maximum of four transmitters can be programmed. Programming mode will exit after 30 seconds.
Chrysler Sebring Town and Country Dodge Pickup R1500 Stratus R/T Caravan Dakota Durango
Programming is by scan tool or by “customer learn” mode.
Jeep Liberty
Up to four transmitters can be stored.
1. Press and release any button on the same transmitter. If the code is successfully learned, the chime will sound. 2. To program additional transmitters, repeat steps 4 and 5. 3. Turn ignition off.
Ford Focus
Maximum of four transmitters can be programmed.
1. 2. 3. 4. 5.
If no functioning transmitter is available the scan tool must be used. Programming mode will cancel 60 seconds after the chimes stop in step 3. All programming must be completed within this time period.
All transmitters must be programmed at the same time. Programming mode will exit if: • The engine is started. • The 10 second time expires. • Four transmitters are programmed. Ford F150 Pickup Explorer
All transmitters must be programmed at the same time. RKE transmitters can also be programmed using a scan tool.
Taurus Programming mode will exit if: Escape Expedition Excursion Ranger Lincoln
• The key is turned off. • The 20 second time expires. • The maximum number of transmitters are programmed (depends on vehicle).
CUSTOMER LEARN MODE 1. Turn ignition to run and wait until the chimes stop or fasten seat belt to cancel chimes. 2. Using any original working transmitter, press and hold the unlock button for 4 to 10 seconds. 3. While holding the unlock button, press the panic button for 1 second. Chime will sound for 3 seconds to indicate programming mode is ready. 4. Press lock and unlock buttons together for 1 second and release.
Enter vehicle. Close all doors. Turn ignition switch from ACC to run, four times within 6 seconds. Turn ignition switch to off. Chime will sound to indicate ready to program. Within 10 seconds press any button on the transmitter. A chime will indicate code accepted. 6. To program additional transmitters repeat step 5.
1. Electrically unlock the doors using the RKE transmitter of door lock switch. 2. Turn the key from off to run, eight times within 10 seconds, ending with the key on. The module will lock and unlock the doors, indicating program mode. 3. Within 20 seconds press any button on the transmitter. The locks will cycle to indicate the transmitter has been learned. 4. Repeat step 3 for any additional RKE transmitters. 5. Turn the key off to exit the programming mode.
Navigator Mazda B2300 Mercury Mountaineer Mariner CHART 59–1
(CONTINUED)
Continued
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Infiniti
Key fob codes can be checked and changed using a scan tool.
1. Enter the vehicle and close all doors. 2. Insert and then completely remove key from the ignition cylinder more than six times within 10 seconds. Hazard warning lamps will flash twice to indicate programming mode is active. 3. Insert the key and turn the ignition to ACC. 4. Press any key on the fob once. The hazard warning lamps will flash twice to indicate that the code is stored. 5. To end programming mode open the driver’s door. If programming additional fobs proceed to step 6 (don’t open the driver’s door). 6. To enter an additional code unlock and then lock the driver’s door using the window main switch. 7. Press any button on the additional fob. The hazard warning lamps will flash twice to indicate the code is learned. 8. To enter another key fob code repeat steps 6 and 7. 9. Open the driver’s door to end programming mode.
G20 G35
If step 2 is done too fast, the system will not enter programming mode.
FX35 Q45
Up to five key fobs can be registered. If more than five are input, the oldest ID code will be overwritten. It is possible to enter the same key code into all five memories. This can be used to erase the ID code of a fob that has been lost, if needed.
Lincoln Town Car Continental
All RKE transmitters must be programmed at the same time. RKE transmitters can also be programmed using a scan tool.
Navigator Mercury Grand Marquis
Additional transmitters must be programmed within 7 seconds or the process will have to be repeated from step 1.
1. Turn the key from off to run, eight times (four times for early systems) within 10 seconds, ending with the key on. The module will lock and unlock the doors, indicating program mode. 2. Press any button on the transmitter. Doors will lock and unlock to confirm programming success. 3. To program additional repeat step 2 within 7 seconds. 4. Wait 7 seconds or turn the key off to exit programming mode.
Wait at least 20 seconds after exiting programming mode to test the RKE transmitters. Mazda 5 6
Start with the key out and all doors, trunk lid, and lift gate closed. A total of three transmitters can be programmed. Previously programmed transmitters may be erased during this procedure. If possible, program all desired transmitters at the same time.
Mazda 626 Millenia
Start with the key out and all doors, trunk lid, and lift gate closed. A total of three transmitters can be programmed.
Protégé Previously programmed transmitters may be erased during this procedure. If possible, program all desired transmitters at the same time. Protégé will cycle locks instead of sounding a buzzer.
1. Open the driver’s side door. 2. Put the key in the ignition lock and turn the ignition to on and back to lock, three times (ending in the lock position with the key in the ignition). 3. Close and then open the driver’s door three times, ending with the door open. The door locks will lock and unlock. 4. Push the unlock button on the transmitter twice. Door locks will lock and unlock to verify programming is okay. 5. Repeat step 4 for any additional transmitter to be programmed. 6. When the last transmitter to be programmed has been learned, push the unlock button twice on that transmitter to exit programming mode. 1. Open the driver’s side door. 2. Put the key in the ignition lock and turn the ignition to on and back to lock, three times, then remove the key. 3. Close and then open the driver’s door three times, ending with the door open. A buzzer will sound from the CPU. 4. Push any button on the transmitter twice. Buzzer will sound once to verify programming is okay. 5. Repeat step 4 for any additional transmitter to be programmed. 6. When the last transmitter to be programmed has been learned, push any button twice on that transmitter. The buzzer will sound twice to exit programming mode.
CHART 59–1 Remote keyless programming steps for popular vehicles. Procedures may also apply to similar vehicles by the same manufacturer. Always refer to service information for specific vehicles.
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PROCEDURE
Nissan
Key fob codes can also be checked and changed using a scan tool.
1. Enter the vehicle and close all doors. 2. Insert and then completely remove key from the ignition cylinder more than six times within 10 seconds. Hazard warning lamps will flash twice to indicate programming mode is active. 3. Insert the key and turn the ignition to ACC. 4. Press any key on the fob once. The hazard warning lamps will flash twice to indicate that the code is stored. 5. To end programming mode, open the driver’s door. If programming additional fobs proceed to step 6 (don’t open the driver’s door). 6. To enter an additional code unlock and then lock the driver’s door using the window main switch. 7. Press any button on the additional fob. The hazard warning lamps will flash twice to indicate the code is learned. 8. To enter another key fob code repeat steps 6 and 7. 9. Open the driver’s door to end programming mode.
Altima Armada
If step 2 is done too fast, the system will not enter programming mode.
Frontier Maxima Murano Titan
Pontiac Vibe
Up to five key fobs can be registered. If more than five are input, the oldest ID code will be overwritten. It is possible to enter the same key code into all five memories. This can be used to erase the ID code of a fob that has been lost, if needed.
Up to four transmitters can be programmed.
xB
If more than four transmitters are programmed, the oldest transmitter code will be overwritten.
Toyota
There are four programming modes:
Scion
Camry Corolla
• Add mode: Used to program additional transmitters • Rewrite mode: Erases all previously programmed transmitters • Confirmation mode: Indicates how many transmitters are already programmed • Prohibition mode: Erases all learned codes and disables the wireless entry system In confirmation mode, if no codes are stored the door locks will cycle five times. Open any door to exit the programming mode.
Pontiac G6 Saturn Ion L300
A scan tool is used to program key fobs. Up to four transmitters can be programmed. If any key fob is programmed, all fobs must be programmed at the same time. On vehicles with personalization features, the transmitters are numbered 1 and 2. The first transmitter programmed will become driver 1 and the second will become driver 2.
CHART 59–1
1. Enter the vehicle, key out of ignition, close all doors except the driver’s door. 2. Insert and remove the key from the ignition twice within 5 seconds. 3. Close and open the driver’s door twice within 40 seconds and then insert the key and remove it. 4. Close and open the driver’s door twice again, then insert the ignition key and close the door. 5. Turn the key from lock to on and back to lock to select the programming mode: • One time for add mode (go to step 6) • Two times for rewrite mode (go to step 6) • Three times for confirmation mode (go to step 10) • Five times for prohibition mode (see step 11) 6. Remove the key from the ignition. 7. The doors will lock-unlock once for add mode or twice for rewrite mode. 8. To program a transmitter, press lock and unlock buttons for 1.5 seconds and release; then within 3 seconds press either button for more than 1 second to confirm programming: • One lock-unlock cycle indicates okay. • Two lock-unlock cycles indicates not okay; repeat this step. 9. Repeat step 8 to program additional transmitters. 10. In confirmation mode the number of lock-unlock cycles will indicate the number of codes already stored and programming mode will exit. Example: Two cycles indicates two codes are stored. 11. If prohibition mode is selected the locks will cycle five times and programming mode will exit. 1. Install the scan tool and navigate to the Program Key Fobs menu. 2. Select the number of fobs to be programmed. 3. Press and hold the lock and unlock buttons on the first fob to be programmed. The locks should cycle to indicate okay. NOTE: This fob becomes driver 1 key fob. 4. Repeat step 3 for the second fob. This fob becomes driver 2 key fob. 5. Repeat step 3 for any other key fobs to be programmed. 6. Turn off and remove the scan tool to exit programming.
(CONTINUED)
Continued
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Saab
Up to four transmitters can be programmed.
1. Sit in the driver’s seat and close all doors. 2. Open and close the driver’s door. 3. Turn the ignition switch from on to lock, 10 times within 15 seconds. The horn will chirp to indicate programming mode. 4. Open and close the driver’s door. 5. Press any button on the fob to be programmed. 6. The horn will chirp two times to indicate that the transmitter has been learned. 7. Repeat steps 4, 5, and 6 for any additional transmitters. 8. To exit from programming mode remove the key from the ignition. The horn should chirp three times to confirm.
A scan tool is used to program RKE codes.
1. Install the scan tool and navigate to the keyless transmitter ID registration menu. 2. Input the transmitter eight-digit ID number into the scan tool. 3. When the number is correct, press yes. 4. The scan tool will display “ID registration done” when the ID is programmed. 5. Follow the scan tool menus to program additional transmitters.
9-2
Subaru Forester Impreza
Up to four RKE transmitters can be registered.
Legacy Outback Tribeca Toyota Tundra Sequoia Lexus
The eight-digit code is on the plastic bag of a new transmitter on the circuit board inside the transmitter. Up to four transmitters can be programmed. If more than four transmitters are programmed, the oldest transmitter code will be overwritten.
GS 430
There are four programming modes:
RX 300
• Add mode: Used to program additional transmitters • Rewrite mode: Erases all previously programmed transmitters • Confirmation mode: Indicates how many transmitters are already programmed • Prohibition mode: Erases all learned codes and disables the wireless entry system In confirmation mode, if no codes are stored the door locks will cycle five times. Open any door to exit the programming mode.
1. Enter the vehicle, key out of ignition, close all doors except the driver’s door. 2. Insert and remove the key from the ignition key cylinder. 3. Use the driver’s door lock control switch to lock and unlock the doors five times, at about 1 second intervals. 4. Close and open the driver’s door. 5. Use the driver’s door lock control switch to lock and unlock the doors five times, at about 1 second intervals. 6. Insert the ignition key. 7. Turn the key from lock to on and back to lock to select the programming mode: • One time for add mode (go to step 10) • Two times for rewrite mode (go to step 10) • Three times for confirmation mode (go to step 12) • Five times for prohibition mode (see step 13) 8. Remove the key from the ignition. 9. The doors will lock-unlock once, twice, three times of five times to confirm the mode. 10. To program a transmitter press lock and unlock buttons for 1.5 seconds and release; then within 3 seconds press either button for more than 1 second to confirm programming: One lock-unlock cycle indicates okay. Two lock-unlock cycles indicates not okay; repeat this step. 11. Repeat step 10 to program additional transmitters. 12. In confirmation mode the number of lock-unlock cycles will indicate the number of codes already stored and programming mode will exit. Example: Two cycles indicates two codes are stored. 13. If prohibition mode is selected the locks will cycle five times and programming mode will exit.
CHART 59–1 Remote keyless programming steps for popular vehicles. Procedures may also apply to similar vehicles by the same manufacturer. Always refer to service information for specific vehicles.
ANTITHEFT SYSTEMS PARTS AND OPERATION
Antitheft devices flash lights or sound an alarm if the vehicle is broken into or vandalized. In addition to the alarm, some systems prevent the engine from starting by disabling the starter, ignition, or fuel system once the antitheft
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device is activated. Others permit the engine to start, but then disable it after several seconds. Switches in the doorjambs, trunk, and hood provide an input signal to the control module should an undesirable entry occur on a typical system. Some antitheft systems are more complex and also have electronic sensors that trigger the alarm if there is a change in battery current draw, a violent vehicle motion, or if glass is broken. These sensors also provide an input signal to the control module, which may be a separate antitheft
DOOR SWITCH
FIGURE 59–28 A shock sensor used in alarm and antitheft systems. If the vehicle is moved, the magnet will move relative to the coil, inducing a small voltage that will trigger the alarm.
FRONT DOORS 1
unit or incorporated into the PCM or BCM. SEE FIGURE 59–28 on page 360 for an example of a shock sensor used in an antitheft alarm system.
ANTITHEFT SYSTEM DIAGNOSIS
REAR DOORS 1
FIGURE 59–29 Door switches, which complete the ground circuit with the door open, are a common source of high resistance.
Most factory-installed antitheft systems are integrated with several other circuits to form a complex, multiple-circuit system. The major steps are as follows: 1. It is essential to have accurate diagrams, specifications, and test procedures for the specific model being serviced. 2. The easiest way to reduce circuit complexity is to use the wiring diagram to break the entire system into its subcircuits, then check only those related to the problem. 3. If any step indicates that a subcircuit is not complete, check the power source, ground, components, and wiring in that subcircuit. Many systems use a computer chip in the plastic part of the key. Most systems are electronically regulated and have a self-diagnostic program. This self-diagnostic program is generally accessed and activated using a scan tool. Diagnostic and test procedures are similar as for any of the other electronic control systems used on the vehicle.
ANTITHEFT SYSTEM TESTING AND SERVICE
Before performing any diagnostic checks, make sure that all of the following electrical devices function correctly.
Parking and low-beam headlights
Dome and courtesy lights
Horn
Electric door locks
Circuit information from these devices often provides basic inputs to the control module. If a problem is detected in any of these circuits, such as a missing signal or a signal that is out of range, the control module disables the antitheft system and may record a diagnostic trouble code (DTC). If all of the previously mentioned devices are operational, check all the circuits leading to the antitheft control module. Make
FIGURE 59–30 A special tool is needed to diagnose a General Motors VATS security system and special keys that contain a resistor pellet.
sure all switches are in their normal or off positions. Doorjamb switches complete the ground circuit when a door is opened. SEE FIGURE 59–29. Frequently, corrosion that builds up on the switch contacts prevents the switch from operating properly. Conduct voltage drop tests to isolate faulty components and circuit problems. Repair as needed and retest to confirm that the system is operational. Follow procedures from the manufacturer to clear DTC records, and then run the self-diagnostic program to verify repairs. Some system diagnostic procedures specify the use of special testers. SEE FIGURE 59–30. SEE CHART 59–2 for programming procedures for selected vehicles.
ACCESSORY CIRCUITS
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Chrysler
Programming is by scan tool or by “customer learn” mode.
Pacifica Town and Country
Customer learn mode requires at least two functioning Sentry keys.
PT Cruiser Sebring 300 Some other models Dodge Caravan Durango Magnum Neon Pickup Stratus Jeep
If no functioning Sentry keys are available, the scan tool and the vehicle PIN number are required for programming. Both the immobilizer and RKE are programmed with this procedure. Only a blank key transponder can be programmed. Once programmed, the key cannot be used in another vehicle. The customer learn mode will exit after each key is programmed. The complete procedure must be completed for each key to be programmed.
PROCEDURES CUSTOMER LEARN MODE 1. Using a blank Sentry key, cut the key to match the lock cylinder code. 2. Insert one of the two valid keys into the ignition and turn the ignition on. 3. After 3 seconds, but before 15 seconds expire, turn off the ignition and remove the key. 4. Within 15 seconds insert the second valid key and turn the ignition on. 5. Within 10 seconds a chime will sound and/or the indicator lamp will flash, indicating customer learn mode is active. 6. Within 60 seconds turn the ignition off, insert the blank Sentry key, and turn the ignition on. 7. After about 10 seconds a single chime will sound and the indicator lamp will stay on solid for about 3 seconds; this indicates the key has been programmed.
A total of eight keys can be programmed by the Sentry Key Remote Entry Module (four on some models).
Liberty Grand Cherokee Some other models Ford Taurus Some other models Lincoln
This procedure requires two or more programmed keys. If two programmed keys are not available a scan tool must be used. Maximum of eight keys can be programmed.
Some models Mercury Grand Marquis Milan Montego Ford Crown Victoria Some other models
Repeat the complete procedure for each key to be learned. If the programming is not successful the antitheft indicator will flash and the vehicle will not start. Leave the key on for 30 seconds and then retry the procedure. This procedure requires two or more programmed keys. If two programmed keys are not available a scan tool must be used. Maximum of eight keys can be programmed. Repeat the complete procedure for each key to be learned. If the programming is not successful the antitheft indicator will flash and the vehicle will not start. Leave the key on for 30 seconds and then retry the procedure.
General Motors Passkey
The Passkey decoder will learn the first pellet read when the decoder module is first installed. This learned value cannot be changed.
Passkey II (except vehicles with BCM)
A Passkey Interrogator special tool is needed to read key pellet resistance when replacing keys. The tool will read out a code number related to the pellet resistance.
1. Using the first programmed key, turn the ignition from off to run. Leave the switch in run for at least 3 seconds but not more than 10 seconds. 2. Turn the switch to off. Within 10 seconds repeat step 1 with the second programmed key. 3. Turn the ignition switch off. 4. Within 20 seconds, insert the un-programmed key and turn the ignition switch from off to run. 5. After 3 seconds, attempt to start the vehicle. If the programming is successful the vehicle will start and the antitheft indicator will light for 3 seconds and go out. 1. Using the first programmed key, turn the ignition from off to run. Leave the switch in run for 1 second. 2. Turn the switch to off. Within 5 seconds repeat step 1 with the second programmed key. 3. Turn the ignition switch off. 4. Within 10 seconds, insert the un-programmed key and turn the ignition switch from off to run. 5. After 1 second, attempt to start the vehicle. If the programming is successful the vehicle will start and the antitheft indicator will light for 3 seconds and go out. NEW DECODER MODULE 1. Install the new decoder module. 2. Insert the key and start the vehicle to program the pellet code into the new module. DUPLICATE KEY 1. Use the Interrogator tool to read the existing key code. 2. Obtain a key with the matching pellet code and cut the key to match the original key.
CHART 59–2 Immobilizer or vehicle theft deterrent key learn procedures for some popular vehicles.
680
MAKE/MODEL
NOTES PELLET CODE
General Motors Passkey II (vehicles with BCM)
PROCEDURES RESISTANCE
1
402
2
523
3
681
4
887
5
1,130
6
1,470
7
1,870
8
2,370
9
3,010
10
3,740
11
4,750
12
6,040
13
7,500
14
9,530
15
11,800
On vehicles with a body control module (BCM) the Passkey II pellet code is stored in the BCM. The BCM can learn the pellet code of a replacement key using a scan tool or this procedure. Make sure that the battery is fully charged. If the learning procedure is not successful check the system for codes and repair.
General Motors Passkey III Passkey III⫹
Quick-Learn requires at least one programmed master (black) key. Keys can be learned with a scan tool. If no programmed master key is available the 30 minute Auto Learn procedure must be used.
LOST KEY 1. The Interrogator tool must be used to determine the stored code. 2. Cut a blank key so that the ignition can be turned. 3. Access the lock cylinder 2 wire connector and connect it to the Interrogator. 4. Alternately select each of the 15 code positions on the Interrogator until the vehicle starts. This is then the correct pellet code. 5. Obtain the correct coded key and cut it to fit.
1. Insert the key to be learned and turn the ignition on. Leave the switch on for 11 minutes. The security lamp will be on or flashing during this time. 2. When the security lamp goes off turn the ignition off for 30 seconds. 3. Repeat step 1 two more times. 4. Turn the ignition off for 30 seconds. 5. Attempt to start the vehicle. The vehicle should start and run if the learn is successful. QUICK LEARN 1. Insert a programmed master key and turn on the ignition. 2. Turn the ignition off and remove the key. 3. Within 10 seconds insert the key to be learned and turn the ignition on. 4. The key is now programmed.
Auto Learn procedure will erase all learned keys. 30 MINUTE AUTO LEARN Make sure that the battery is fully charged. On vehicles with a driver information center (DIC) a “STARTING DISABLED DUE TO THEFT” message will display during the 10 minute timer.
General Motors Passlock (early systems)
Passlock systems do not have coded keys. Replacement or new keys do not have to be learned. Early Passlock systems pass an “R” code to the instrument cluster and then the IPC sends a password on to the PCM. Perform this procedure if replacing the instrument cluster, lock cylinder, or PCM.
General Motors Passlock (later models)
CHART 59–2
Replacement or additional keys do not have to be learned. Programming is necessary if the Passlock sensor, BCM, or PCM has been replaced.
1. Insert the new master key and turn on the ignition. The security lamp should be on and then turn it off after 10 minutes. 2. Turn the ignition off for 5 seconds. 3. Repeat steps 1 and 2 two more times (30 minutes total). 4. From the off position turn on and start the vehicle. 5. The vehicle should start and run, indicating the key has been learned. 1. After parts are installed, attempt to start the vehicle. 2. The vehicle should start and stall. 3. Leave the key on and wait until the flashing theft lamp stays on steady. 4. Attempt to start the vehicle again. It should start and continue to run. 5. The theft lamp should flash for 10 seconds and then go out to indicate the password has been learned. 1. Turn the ignition on and attempt to start the vehicle. 2. The vehicle will not start. Release the key to on. Wait about 10 minutes for the security lamp to go off. 3. Turn off the ignition for 5 seconds. (CONTINUED)
Continued
681
MAKE/MODEL
NOTES
PROCEDURES
A scan tool can also be used to program the Passlock system.
4. Repeat steps 1 through 3 two more times. 5. For a fourth time turn the key on and start the vehicle. The vehicle should start and run, indicating that the lock code has been learned.
SEE FIGURE 59–31. Honda
A programmed key, scan tool, and password are required to program keys.
1. Connect the scan tool and navigate to the ADD and DELETE KEYS menu. 2. Follow the instructions on the scan tool to add or delete keys as needed.
Hyundai
A scan tool can be used to program keys.
1. Using the ID key, turn the ignition on then off. 2. Using the key to be programmed, turn the ignition on then off. This will program the key. 3. Repeat step 2 for any additional keys.
A special ID key is needed to program new or additional keys. Toyota
Up to seven master (black) keys can be learned.
Camry
An already learned master key must be used to initiate the procedure.
Land Cruiser Some other earlier models
Toyota
Keys can also be programmed with a scan tool.
Up to five keys can be learned.
Corolla
A scan tool should be used to register keys.
Matrix Tacoma Sienna RAV4 Some other late models Lexus
1. Insert a programmed master key into the ignition switch. 2. Within 15 seconds, press and release the accelerator pedal five times. 3. Within 20 seconds, press and release the brake pedal six times. 4. Remove the master key. 5. Within 10 seconds, insert the key to be programmed into the lock cylinder and press and release the accelerator pedal one time. 6. The security indicator should flash for about 1 minute and then go out to indicate that the key has been learned. 7. To program additional keys repeat steps 5 and 6 within 10 seconds. 1. Insert a programmed master key into the ignition and turn the ignition on. 2. Install the scan tool and navigate to the IMMOBILIZER, TRANSP CODE REG. screen. Follow the instructions on the scan tool. 3. The security indicator will turn on. Within 20 seconds, remove the master key. 4. Within 10 seconds, insert the new key to be programmed. 5. The security indicator will blink for 60 seconds and then go off when the key is learned.
LS430 Some other models CHART 59–2 Immobilizer or vehicle theft deterrent key learn procedures for some popular vehicles. IGNITION HOUSING
RESISTORS
POWER DATA (SIGNAL) GROUND
BCM
HALF EFFECT SENSORS MAGNET
B+
IGN
IGNITION CYLINDER
CONVENTIONAL IGNITION KEY
FIGURE 59–31 The Passlock series of General Motors security systems uses a conventional key. The magnet is located in the ignition lock cylinder and triggers the Hall-effect sensors.
682
FIGURE 59–32 Corrosion or faults at the junction between the wiring and the rear window electrical grid are the source of many rear window defogger problems.
ELECTRICAL ACCESSORY SYMPTOM GUIDE Cruise Control Problem Cruise (speed) control is inoperative.
Power windows are inoperative.
2. Binding or obstruction
Possible Causes and/or Solutions
4. Defective solenoid(s) or wiring to the solenoid(s)
1. Blown fuse 2. Defective or misadjusted electrical or vacuum safety switch near the brake pedal arm
4. Defective transducer; defective speed control switch
Power Windows Problem
1. “Flex” in the cables from the motor(s) to check for motor operation (If flex is felt, the motor is trying to operate the gear nut or the screw jack.) 3. Defective motor (The click is generally the relay sound.)
3. Lack of engine vacuum to servo or transducer
Cruise (speed) control speed is incorrect or variable.
Power seats are inoperative, click is heard.
1. Misadjusted activation cable 2. Defective or pinched vacuum hose
All power seat functions are operative except one.
1. Defective motor 2. Defective solenoid or wiring to the solenoid
Electric Power Door Lock Problem
Possible Causes and/or Solutions
Power door locks are inoperative.
1. Defective circuit breaker, fuse, or wiring to the switch or relay (if used) 2. Defective relay (if used); defective switch
3. Misadjustment of transducer
3. Defective door lock solenoid or ground for solenoid (if solenoid operated) 4. Open in the wiring to the door lock solenoid or the motor
Possible Causes and/or Solutions 1. Defective (blown) fuse (circuit breaker)
5. Mechanical obstruction of the door lock mechanism
2. Defective relay (if used) 3. Poor ground for master control switch 4. Poor connections at switch(es) or motor(s)
Only one door lock is inoperative.
2. Defective door lock solenoid or motor; poor electrical connection at the motor or solenoid
5. Open circuit (usually near the master control switch) 6. Defective lockout switch One power window is inoperative.
1. Defective motor; defective or open control switch 2. Open or loose wiring to the switch or the motor
Only one power window can be operated from the master switch. Power Seats Problem Power seats are inoperative, no click or noise.
1. Defective switch; poor ground on the solenoid (if solenoid operated)
Rear Window Defogger Problem Rear window defogger is inoperative.
1. Poor connection or open circuit in the control wire(s)
Possible Causes and/or Solutions 1. Proper operation by performing breath test and/or voltmeter (Check at the power side of the rear window grid.); defective relay or timer assembly 2. Defective switch 3. Open ground connection at the rear window grid ( SEE FIGURE 59–32.) NOTE: If there is an open circuit (power side or ground side), the dash indicator light will still operate in most cases.
Possible Causes and/or Solutions 1. Defective circuit breaker 2. Poor ground at the switch or relay (if used) 3. Open in the wiring between the switch and relay (if used); defective switch
Rear window defogger cleans only a portion of the rear window.
1. Broken grid wire(s) or poor electrical connections at either the power side or the ground side of the wire grid
4. Defective solenoid(s) or wiring 5. Defective door switch
ACCESSORY CIRCUITS
683
DOOR PANEL REMOVAL
1
Looking at the door panel there appears to be no visible fasteners.
2
Gently prying at the edge of the light shows that it snaps in place and can be easily removed.
3
Under the red “door open” warning light is a fastener.
4
Another screw is found under the armrest.
5
A screw is removed from the bezel around the interior door handle.
6
The electric control panel is held in by clips.
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STEP BY STEP
7
Another screw is found after the control panel is removed.
8
9
A gentle tug and the door panel is removed.
10
The sound-deadening material also acts as a moisture barrier and would need to be removed to gain access to the components inside the door.
12
Align and press the door panel clips into the openings and reinstall all of the fasteners and components.
11
Carefully inspect the door panel clips before reinstalling the door panel.
The panel beside the outside mirror is removed by gentle prying.
ACCESSORY CIRCUITS
685
REVIEW QUESTIONS 1. How do power door locks on a four-door vehicle function with only one ground wire connection?
3. What is the usual procedure to follow to resynchronize a remote keyless entry transmitter?
2. How does a rear window defogger regulate how much current flows through the grids based on temperature?
4. How do heated and cooled seats operate?
CHAPTER QUIZ 1. The owner of a vehicle equipped with cruise control complains that the cruise control often stops working when driving over rough or bumpy pavement. Technician A says the brake switch may be out of adjustment. Technician B says a defective servo unit is the most likely cause. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 2. Technician A says that the cruise control on a vehicle that uses an electronic throttle control (ETC) system uses a servo to move the throttle. Technician B says that the cruise control on a vehicle with ETC uses the APP sensor to set the speed. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 3. All power windows fail to operate from the independent switches but all power windows operate from the master switch. Technician A says the window lockout switch may be on. Technician B says the power window relay could be defective. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 4. Technician A says that a defective ground connection at the master control switch (driver’s side) could cause the failure of all power windows. Technician B says that if one control wire is disconnected, all windows will fail to operate. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 5. A typical radar cruise control system uses ________. a. Long-range radar (LRR) b. Short-range radar (SRR) c. Electronic throttle control system to control vehicle speed d. All of the above
chapter
60
6. When checking the operation of a rear window defogger with a voltmeter, ________. a. The voltmeter should be set to read AC volts b. The voltmeter should read close to battery voltage anywhere along the grid c. Voltage should be available anytime at the power side of the grid because the control circuit just completes the ground side of the heater grid circuit d. The voltmeter should indicate decreasing voltage when the grid is tested across the width of the glass 7. PM motors used in power windows, mirrors, and seats can be reversed by ________. a. Sending current to a reversed field coil b. Reversing the polarity of the current to the motor c. Using a reverse relay circuit d. Using a relay and a two-way clutch 8. If only one power door lock is inoperative, a possible cause is a ________. a. Poor ground connection at the power door lock relay b. Defective door lock motor (or solenoid) c. Defective (open) circuit breaker for the power circuit d. Defective (open) fuse for the control circuit 9. A keyless remote control stops working. Technician A says the battery in the remote could be dead. Technician B says that the key fob may have to be resynchronized. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 10. Two technicians are discussing antitheft systems. Technician A says that some systems require a special key. Technician B says that some systems use a computer chip in the key. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
AIRBAG AND PRETENSIONER CIRCUITS
OBJECTIVES: After studying Chapter 60, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “H” (Accessories Diagnosis and Repair). • List the appropriate safety precautions to be followed when working with airbag systems. • Describe the procedures to diagnose and repair common faults in airbag systems. • Explain how the passenger presence system works.
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CHAPTER 60
KEY TERMS: Airbag 687 • Arming sensor 689 • Clockspring 691 • Deceleration sensor 690 • Dual-stage airbags 691 • EDR 697 • Integral sensor 690 • Knee airbags 694 • Occupant detection systems (ODS) 695 • Passenger presence system (PPS) 695 • Pretensioners 687 • SAR 688 • Side airbags 696 • SIR 688 • Squib 689 • SRS 688
SEE FIGURE 60–2 for an example of an inertia-type seat belt locking mechanism.
SAFETY BELTS AND RETRACTORS
SAFETY BELT LIGHTS AND CHIMES
SAFETY BELTS
Safety belts are used to keep the driver and passengers secured to the vehicle in the event of a collision. Most safety belts include three-point support and are constructed of nylon webbing about 2 in. (5 cm) wide. The three support points include two points on either side of the seat for the belt over the lap and one crossing over the upper torso, which is attached to the “B” pillar or seat back. Every crash consists of three types of collisions. Collision 1: The vehicle strikes another vehicle or object. Collision 2: The driver and/or passengers hit objects inside the vehicle if unbelted.
Collision 3: The internal organs of the body hit other organs or bones, which causes internal injuries. If a safety belt is being worn, the belt stretches, absorbing a lot of the impact, thereby preventing collision with other objects in the vehicle and reducing internal injuries. SEE FIGURE 60–1.
BELT RETRACTORS
Safety belts are also equipped with one of the following types of retractors.
Nonlocking retractors, which are used primarily on recoiling
Emergency locking retractors, which lock the position of the safety belt in the event of a collision or rollover
Emergency and web speed-sensitive retractors, which allow freedom of movement for the driver and passenger but lock if the vehicle is accelerating too fast or if the vehicle is decelerating too fast.
STOPPING DISTANCE OF DRIVER STOPPING DISTANCE OF VEHICLE
FORCE ON 160 LB. DRIVER IS 3200 LB. (20 G'S)
All late-model vehicles are equipped with a safety belt warning light on the dash and a chime that sounds if the belt is not fastened. SEE FIGURE 60–3. Some vehicles will intermittently flash the reminder light and sound a chime until the driver and sometimes the front passenger fasten their safety belts.
PRETENSIONERS
A pretensioner is an explosive (pyrotechnic) device that is part of the seat belt retractor assembly and tightens the seat belt as the airbag is being deployed. The purpose of the pretensioning device is to force the occupant back into position against the seat back and to remove any slack in the seat belt. SEE FIGURE 60–4. CAUTION: The seat belt pretensioner assemblies must be replaced in the event of an airbag deployment. Always follow the vehicle manufacturer’s recommended service procedure. Pretensioners are explosive devices that could be ignited if voltage is applied to the terminals. Do not use a jumper wire or powered test light around the wiring near the seat belt latch wiring. Always follow the vehicle manufacturer’s recommended test procedures.
FRONT AIRBAGS PURPOSE AND FUNCTION
Airbag passive restraints are designed to cushion the driver (or passenger, if the passenger side is so equipped) during a frontal collision. The system consists of one
STOPPING DISTANCE OF DRIVER AND VEHICLE
1.5 FT
1 FT
1 FT SEAT BELT STRETCH
FORCE ON 160 LB. DRIVER IS 4800 LB. (30 G'S)
CRASH SCENARIO WITH VEHICLE STOPPING IN ONE FOOT DISTANCE FROM A SPEED OF 30 MPH.
FIGURE 60–1 (a) Safety belts are the primary restraint system. (b) During a collision the stretching of the safety belt slows the impact to help reduce bodily injury.
AIRBAG AND PRETENSIONER CIRCUITS
687
SEAT BELT PRETENSIONER CABLE EXPLOSIVE CHARGE
REST TUBE
FIGURE 60–4 A small explosive charge in the pretensioner forces the end of the seat belt down the tube, which removes any slack in the seat belt. ANGLE AT WHICH A COLLISION MUST OCCUR FOR AN AIRBAG DEPLOYMENT
WEIGHT 30˚
30˚
ACTIVE FORWARD SENSOR
FIGURE 60–2 Most safety belts have an inertia-type mechanism that locks the belt in the event of rapid movement.
PASSENGER COMPARTMENT SENSOR
PASSENGER INFLATOR MODULE
FIGURE 60–3 A typical safety belt warning light.
DRIVER INFLATOR MODULE SDM
or more nylon bags folded up in compartments located in the steering wheel, dashboard, interior panels, or side pillars of the vehicle. During a crash of sufficient force, pressurized gas instantly fills the airbag and then deploys out of the storage compartment to protect the occupant from serious injury. These airbag systems may be known by many different names, including the following: 1. Supplemental restraint system (SRS) 2. Supplemental inflatable restraints (SIR) 3. Supplemental air restraints (SAR) Most airbags are designed to supplement the safety belts in the event of a collision, and front airbags are meant to be deployed only in the event of a frontal impact within 30 degrees of center. Front (driver and passenger side) airbag systems are not designed to inflate during side or rear impact. The force required to deploy a
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FIGURE 60–5 A typical airbag system showing many of the components. The SDM is the “sensing and diagnostic module” and includes the arming sensor as well as the electronics that keep checking the circuits for continuity and the capacitors that are discharged to deploy the air bags. typical airbag is approximately equal to the force of a vehicle hitting a wall at over 10 mph (16 km/hr). The force required to trigger the sensors within the system prevents accidental deployment if curbs are hit or the brakes are rapidly applied. The system requires a substantial force to deploy the airbag to help prevent accidental inflation.
PARTS INVOLVED SEE FIGURE 60–5 for an overall view of the parts included in a typical airbag system.
IGNITION POWER ()
ARMING SENSOR
SQUIB (INFLATOR HEATING ELEMENT)
FORWARD DISCRIMINATING SENSOR
PASSENGER COMPARTMENT DISCRIMINATING SENSOR
FIGURE 60–7 The inflator module is being removed from the airbag housing. The squib, inside the inflator module, is the heating element that ignites the pyrotechnic gas generator that rapidly produces nitrogen gas to fill the airbag.
FIGURE 60–6 A simplified airbag deployment circuit. Note that both the arming sensor and at least one of the discriminating sensors must be activated at the same time. The arming sensor provides the power, and either one of the discriminating sensors can provide the ground for the circuit.
The parts include: 1. Sensors 2. Airbag (inflator) module 3. Clockspring wire coil in the steering column 4. Control module 5. Wiring and connectors
OPERATION
To cause inflation, the following events must occur.
To cause a deployment of the airbag, two sensors must be triggered at the same time. The arming sensor is used to provide electrical power, and a forward or discriminating sensor is used to provide the ground connection.
The arming sensor provides the electrical power to the airbag heating unit, called a squib, inside the inflator module.
The squib uses electrical power and converts it into heat for ignition of the propellant used to inflate the airbag.
Before the airbag can inflate, however, the squib circuit also must have a ground provided by the forward or the discriminating sensor. In other words, two sensors (arming and forward sensors) must be triggered at the same time before the airbag will be deployed. SEE FIGURE 60–6.
TYPES OF AIRBAG INFLATORS
There are two different
types of inflators used in airbags. 1. Solid fuel. This type uses sodium azide pellets and, when ignited, generates a large quantity of nitrogen gas that quickly inflates the airbag. This was the first type used and is still commonly used in driver and passenger side airbag inflator modules. SEE FIGURE 60–7. The squib is the electrical heating element used to ignite the gas-generating material, usually sodium azide. It requires about 2 A of current to heat the heating element and ignite the inflator. 2. Compressed gas. Commonly used in passenger side airbags and roof-mounted systems, the compressed gas system uses
FIGURE 60–8 This shows a deployed side curtain airbag on a training vehicle. a canister filled with argon gas, plus a small percentage of helium at 3,000 psi (435 kPa). A small igniter ruptures a burst disc to release the gas when energized. The compressed gas inflators are long cylinders that can be installed inside the instrument panel, seat back, door panel, or along any side rail or pillar of the vehicle. SEE FIGURE 60–8. Once the inflator is ignited, the nylon bag quickly inflates (in about 30 ms or 0.030 second) with nitrogen gas generated by the inflator. During an actual frontal collision accident, the driver is being thrown forward by the driver’s own momentum toward the steering wheel. The strong nylon bag inflates at the same time. Personal injury is reduced by the spreading of the stopping force over the entire upper-body region. The normal collapsible steering column remains in operation and collapses in a collision when equipped with an airbag system. The bag is equipped with two large side vents that allow the bag to deflate immediately after inflation, once the bag has cushioned the occupant in a collision.
TIMELINE FOR AIRBAG DEPLOYMENT
Following are the times necessary for an airbag deployment in milliseconds (each millisecond is equal to 0.001 second or 1/1,000 of a second). 1. Collision occurs: 0.0 ms 2. Sensors detect collision: 16 ms (0.016 second) 3. Airbag is deployed and seam cover rips: 40 ms (0.040 second)
AIRBAG AND PRETENSIONER CIRCUITS
689
NON-MAGNETIC SLEEVE
CRASH SENSOR PERMANENT MAGNET AND POLE PIECE
CONTACT SPRING
ROLLER
VOLTAGE SIGNAL FROM SDM GROUND CIRCUIT TO SDM
GOLD PLATED ELECTRICAL CONTACTS
GOLD PLATED BALL (MASS)
DIRECTION OF TRAVEL
IMPACT STOP CONTROL MODULE CIRCUITS
STAINLESS STEEL RIBBON
A
DURING READINESS (CONTACTS OPEN)
B
DURING DEPLOYMENT (CONTACTS CLOSED)
FIGURE 60–9 An airbag magnetic sensor.
4. Airbag is fully inflated: 100 ms (0.100 second) 5. Airbag deflated: 250 ms (0.250 second)
STAINLESS STEEL RIBBON
ROLLER
FIGURE 60–10 Some vehicles use a ribbon-type crash sensor.
In other words, an airbag deployment occurs and is over in about a quarter of a second.
SENSOR OPERATION
All three sensors are basically switches that complete an electrical circuit when activated. The sensors are similar in construction and operation, and the location of the sensor determines its name. All airbag sensors are rigidly mounted to the vehicle and must be mounted with the arrow pointing toward the front of the vehicle to ensure that the sensor can detect rapid forward deceleration. There are three basic styles (designs) of airbag sensors. 1. Magnetically retained gold-plated ball sensor. This sensor uses a permanent magnet to hold a gold-plated steel ball away from two gold-plated electrical contacts. SEE FIGURE 60–9. If the vehicle (and the sensor) stops rapidly enough, the steel ball is released from the magnet because the inertia force of the crash was sufficient to overcome the magnetic pull on the ball and then makes contact with the two gold-plated electrodes. The steel ball only remains in contact with the electrodes for a relatively short time because the steel ball is drawn back into contact with the magnet. 2. Rolled up stainless-steel ribbon-type sensor. This sensor is housed in an airtight package with nitrogen gas inside to prevent harmful corrosion of the sensor parts. If the vehicle (and the sensor) stops rapidly, the stainless-steel roll “unrolls” and contacts the two gold-plated contacts. Once the force is stopped, the stainless-steel roll will roll back into its original shape. SEE FIGURE 60–10.
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FIGURE 60–11 A sensing and diagnostic module that includes an accelerometer. 3. Integral sensor. Some vehicles use electronic deceleration sensors built into the inflator module, called integral sensors. For example, General Motors uses the term sensing and diagnostic module (SDM) to describe their integrated sensor/ module assembly. These units contain an accelerometer-type sensor which measures the rate of deceleration and, through computer logic, determines if the airbags should be deployed. SEE FIGURE 60–11.
SAFETY TIP Dual-Stage Airbag Caution
CONNECTORS TO EACH STAGE
Many vehicles are equipped with dual-stage airbags (two-stage airbags) that actually contain two separate inflators, one for less severe crashes and one for higher speed collisions. These systems are sometimes called smart airbag systems because the accelerometer-type sensor used can detect how severe the impact is and deploy one or both stages. If one stage is deployed, the other stage is still active and could be accidentally deployed. A service technician cannot tell by looking at the airbag whether both stages have deployed. Always handle a deployed airbag as if it has not been deployed and take all precautions necessary to keep any voltage source from getting close to the inflator module terminals.
INFLATOR MODULE
FIGURE 60–12 A driver’s side airbag showing two inflator connectors. One is for the lower force inflator and the other is for the higher force inflator. Either can be ignited or both at the same time if the deceleration sensor detects a severe impact.
TECH TIP Pocket the Ignition Key to Be Safe
TWO-STAGE AIRBAGS
When replacing any steering gear such as a rack-andpinion steering unit, be sure that no one accidentally turns the steering wheel. If the steering wheel is turned without being connected to the steering gear, the airbag wire coil (clockspring) can become off center. This can cause the wiring to break when the steering wheel is rotated after the steering gear has been replaced. To help prevent this from occurring, simply remove the ignition key from the ignition and keep it in your pocket while servicing the steering gear.
Two-stage airbags, often called advanced airbags or smart airbags, use an accelerometer-type of sensor to detect force of the impact. This type of sensor measures the actual amount of deceleration rate of the vehicle and is used to determine whether one or both elements of a two-stage airbag should be deployed.
Low-stage deployment. This lower force deployment is used if the accelerometer detects a low-speed crash.
High-stage deployment. This stage is used if the accelerometer detects a higher speed crash or a more rapid deceleration rate.
Both low- and high-stage deployment. Under severe highspeed crashes, both stages can be deployed.
SEE FIGURE 60–12.
WIRING
Wiring and connectors are very important for proper identification and long life. Airbag-related circuits have the following features.
All electrical wiring and conduit for airbags are colored yellow.
To ensure proper electrical connection to the inflator module in the steering wheel, a coil assembly is used in the steering column. This coil is a ribbon of copper wires that operates much like a window shade when the steering wheel is rotated. As the steering wheel is rotated, this coil, usually called a clockspring, prevents the lack of continuity between the sensors and the inflator assembly that might result from a horn-ring type of sliding conductor.
Inside the yellow plastic airbag connectors are gold-plated terminals which are used to prevent corrosion.
SEE FIGURE 60–13. Most airbag systems also contain a diagnostic unit that often includes an auxiliary power supply, which is used to provide the current to inflate the airbag if the battery is disconnected from the vehicle during a collision. This auxiliary power supply normally uses capacitors that are discharged through the squib of the inflation module. When the ignition is turned off these capacitors are discharged. Therefore, after a few minutes an airbag system will not deploy if the vehicle is hit while parked.
AIRBAG DIAGNOSIS TOOLS AND EQUIPMENT SELF-TEST PROCEDURE
The electrical portion of airbag systems is constantly checked by the circuits within the airbagenergizing power unit or through the airbag controller. The electrical airbag components are monitored by applying a small-signal voltage from the airbag controller through the various sensors and components. Each component and sensor uses a resistor in parallel with the load or open sensor switch for use by the diagnostic signals. If continuity exists, the testing circuits will measure a small voltage drop. If an open or short circuit occurs, a dash warning light is lighted and a possible diagnostic trouble code (DTC) is stored. Follow exact manufacturer’s recommended procedures for accessing and erasing airbag diagnostic trouble codes. Diagnosis and service of airbag systems usually require some or all of the following items.
Digital multimeter (DMM)
Airbag simulator, often called a load tool
Scan tool
Shorting bar or shorting connector(s)
Airbag system tester
AIRBAG AND PRETENSIONER CIRCUITS
691
RUN A22
ST-RUN A21 JUNCTION BLOCK
POWERTRAIN CONTROL MODULE
DATA LINK CONNECTOR C2
C2 C103
DRIVER AIRBAG C3
CLOCKSPRING NO. 2
C1
BODY CONTROL MODULE
C1
PASSENGER AIRBAG
AIRBAG CONTROL MODULE
G201
FIGURE 60–13 The airbag control module is linked to the powertrain control module (PCM) and the body control module (BCM) on this Chrysler system. Notice the airbag wire connecting the module to the airbag through the clockspring. Both power, labeled “driver airbag high” and ground, labeled “driver airbag low” are conducted through the clockspring.
Vehicle-specific test harness
Special wire repair tools or connectors, such as crimp-andseal weatherproof connectors
SEE FIGURE 60–14. CAUTION: Most vehicle manufacturers specify that the negative battery terminal be removed when testing or working around airbags. Be aware that a memory saver device used to keep the computer and radio memory alive can supply enough electrical power to deploy an airbag.
PRECAUTIONS
Take the following precautions when working with or around airbags.
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1. Always follow all precautions and warning stickers on vehicles equipped with airbags. 2. Maintain a safe working distance from all airbags to help prevent the possibility of personal injury in the unlikely event of an unintentional airbag deployment. Side impact airbag: 5 in. (13 cm) distance Driver front airbag: 10 in. (25 cm) distance Passenger front airbag: 20 in. (50 cm) distance 3. In the event of a collision in which the bag(s) is deployed, the inflator module and all sensors usually must be replaced to ensure proper future operation of the system. 4. Avoid using a self-powered test light around the yellow airbag wiring. Even though it is highly unlikely, a self-powered test light
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FREQUENTLY ASKED QUESTION
What Are Smart Airbags? Smart airbags use the information from sensors to determine the level of deployment. Sensors used include: • Vehicle speed (VS) sensors. This type of sensor has a major effect on the intensity of a collision. The higher the speed is, the greater the amount of impact force. • Seat belt fastened switch. If the seat belt is fastened, as determined by the seat belt buckle switch, the airbag system will deploy accordingly. If the driver or passenger is not wearing a seat belt, the airbag system will deploy with greater force compared to when the seat belt is being worn. • Passenger seat sensor. The sensor in the seat on the passenger’s side determines the force of deployment. If there is not a passenger detected, the passenger side airbag will not deploy on the vehicle equipped with a passenger seat sensor system.
FIGURE 60–14 An airbag diagnostic tester. Included in the plastic box are electrical connectors and a load tool that substitutes for the inflator module during troubleshooting.
could provide the necessary current to accidentally set off the inflator module and cause an airbag deployment. 5. Use care when handling the inflator module section when it is removed from the steering wheel. Always hold the inflator away from your body.
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6. If handling a deployed inflator module, always wear gloves and safety glasses to avoid the possibility of skin irritation from the sodium hydroxide dust, which is used as a lubricant on the bag(s), that remains after deployment.
Why Change Knee Bolsters If Switching to Larger Wheels? Larger wheels and tires can be installed on vehicles, but the powertrain control module (PCM) needs to be reprogrammed so the speedometer and other systems that are affected by a change in wheel/tire size can work effectively. When 20 in. wheels are installed on General Motors trucks or sport utility vehicles (SUVs), GM specifies that replacement knee bolsters be installed. Knee bolsters are the padded area located on the lower part of the dash where a driver or passenger’s knees would hit in the event of a front collision. The reason for the need to replace the knee bolsters is to maintain the crash testing results. The larger 20 in. wheels would tend to be forced farther into the passenger compartment in the event of a front-end collision. Therefore to maintain the frontal crash rating standard, the larger knee bolsters are required.
7. Never jar or strike a sensor. The contacts inside the sensor may be damaged, preventing the proper operation of the airbag system in the event of a collision. 8. When mounting a sensor in a vehicle, make certain that the arrow on the sensor is pointing toward the front of the vehicle. Also be certain that the sensor is securely mounted.
AIRBAG SYSTEM SERVICE DIS-ARMING
The airbags should be dis-armed, (temporarily disconnected), whenever performing service work on any of the follow locations.
Steering wheel
Dash or instrument panel
Glove box (instrument panel storage compartment)
FREQUENTLY ASKED QUESTION
WARNING: Failure to perform the specified changes when changing wheels and tires could result in the vehicle not being able to provide occupant protection as designed by the crash test star rating that the vehicle originally achieved.
Check service information for the exact procedure, which usually includes the following steps. STEP 1
Disconnect the negative battery cable.
STEP 2
Remove the airbag fuse (has a yellow cover).
STEP 3
Disconnect the yellow electrical connector located at the base of the steering column to disable the driver’s side airbag.
STEP 4
Disconnect the yellow electrical connector for the passenger side airbag.
This procedure is called “disabling air bags” in most service information. Always follow the vehicle manufacturer’s specified procedures.
DIAGNOSTIC AND SERVICE PROCEDURE
Airbag system components and their location in the vehicle vary according to system design, but the basic principles of testing are the same as for other electrical circuits. Use service information to determine how the circuit is designed and the correct sequence of tests to be followed.
Some airbag systems require the use of special testers. The built-in safety circuits of such testers prevent accidental deployment of the airbag.
If such a tester is not available, follow the recommended alternative test procedures specified by the manufacturer.
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Access the self-diagnostic system and check for diagnostic trouble code (DTC) records.
FRONT VIEW
HORN BUTTONS
The scan tool is needed to access the data stream on most systems.
STEERING WHEEL
CRUISE CONTROL BUTTONS
SELF-DIAGNOSIS
All airbag systems can detect system electrical faults, and if found will disable the system and notify the driver through an airbag warning lamp in the instrument cluster. Depending on circuit design, a system fault may cause the warning lamp to fail to illuminate, remain lit continuously, or flash. Some systems use a tone generator that produces an audible warning when a system fault occurs or if the warning lamp is inoperative. The warning lamp should illuminate with the ignition key on and engine off as a bulb check. If not, the diagnostic module is likely disabling the system. If the airbag warning light remains on, the airbags may or may not be disabled, depending on the specific vehicle and the fault detected. Some warning lamp circuits have a timer that extinguishes the lamp after a few seconds. The airbag system generally does not require service unless there is a failed component. However, a steering wheel–mounted airbag module is routinely removed and replaced in order to service switches and other column-mounted devices.
KNEE AIRBAGS
Some vehicles are equipped with knee airbags usually on the driver’s side. Use caution if working under the dash and always follow the vehicle manufacturer’s specified service procedures.
DRIVER SIDE AIRBAG MODULE REPLACEMENT For the specific model being serviced, carefully follow the procedures provided by the vehicle manufacturer to disable and remove the airbag module. Failure to do so may result in serious injury and extensive damage to the vehicle. Replacing a discharged airbag is costly. The following procedure reviews the basic steps for removing an airbag module. Do not substitute these general instructions for the specific procedure recommended by the manufacturer. 1. Turn the steering wheel until the front wheels are positioned straight ahead. Some components on the steering column are removed only when the front wheels are straight. 2. Switch the ignition off and disconnect the negative battery cable, which cuts power to the airbag module. 3. Once the battery is disconnected, wait as long as recommended by the manufacturer before continuing. When in doubt, wait at least 10 minutes to make sure the capacitor is completely discharged. 4. Loosen and remove the nuts or screws that hold the airbag module in place. On some vehicles, these fasteners are located on the back of the steering wheel. On other vehicles, they are located on each side of the steering wheel. The fasteners may be concealed with plastic finishing covers that must be pried off with a small screwdriver to access them. 5. Carefully lift the airbag module from the steering wheel and disconnect the electrical connector. Connector location varies: Some are below the steering wheel behind a plastic trim cover; others are at the top of the column under the module. SEE FIGURES 60–15 AND 60–16.
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HORN WIRING HARNESS
STEERING COLUMN CRUISE CONTROL WIRING HARNESS
AIR BAG MODULE AIR BAG ELECTRICAL CONNECTOR
FIGURE 60–15 After disconnecting the battery and the yellow connector at the base of the steering column, the airbag inflator module can be removed from the steering wheel and the yellow airbag electrical connector at the inflator module disconnected.
SHORTING BARS
SHORTING BARS
FIGURE 60–16 Shorting bars are used in most airbag connectors. These spring-loaded clips short across both terminals of an airbag connector when it is disconnected to help prevent accidental deployment of the airbag. If electrical power was applied to the terminals, the shorting bars would simply provide a low-resistance path to the other terminal and not allow current to flow past the connector. The mating part of the connector has a tapered piece that spreads apart the shorting bars when the connector is reconnected.
6. Store the module pad side up in a safe place where it will not be disturbed or damaged while the vehicle is being serviced. Do not attempt to disassemble the airbag module. If the airbag is defective, replace the entire assembly. When installing the airbag module, make sure the clockspring is correctly positioned to ensure module-to-steering-column continuity. SEE FIGURE 60–17. Always route the wiring exactly as it was before removal. Also, make sure the module seats completely into the steering wheel. Secure the assembly using new fasteners, if specified.
FIGURE 60–17 An airbag clockspring showing the flat conductor wire. It must be properly positioned to ensure proper operation.
SAFETY WHEN MANUALLY DEPLOYING AIRBAGS Airbag modules cannot be disposed of unless they are deployed. Do the following to prevent injury when manually deploying an airbag.
When possible, deploy the airbag outside of the vehicle. Follow the vehicle manufacturer’s recommendations.
Follow the vehicle manufacturer’s procedures and equipment recommendations.
Wear the proper hearing and eye protection.
Deploy the airbag with the trim cover facing up.
Stay at least 20 ft (6 m) from the airbag. (Use long jumper wires attached to the wiring and routed outside the vehicle to a battery.)
Allow the airbag module to cool.
FIGURE 60–18 An airbag being deployed as part of a demonstration in an automotive laboratory.
SEE FIGURE 60–18.
OCCUPANT DETECTION SYSTEMS
FIGURE 60–19 A dash warning lamp will light if the passenger side airbag is off because no passenger was detected by the seat sensor.
PURPOSE AND FUNCTION
The U.S. Federal Motor Vehicle Safety Standard 208 (FMVSS) specifies that the passenger side airbag be disabled or deployed with reduced force under the following conditions. This system is referred to as an occupant detection system (ODS) or the passenger presence system (PPS).
When there is no weight on the seat and no seat belt is fastened, the passenger side airbag will not deploy and the passenger airbag light should be off. SEE FIGURE 60–19. The passenger side airbag will be disabled and the disabled airbag light will be on if only 10 to 37 lb (4.5 to 17 kg) is on the passenger seat, which would generally represent a seated child.
If 38 to 99 lb (17 to 45 kg) is detected on the passenger seat, which represents a child or small adult, the airbag will deploy at a decreased force.
If 99 lb (45 kg) or more is detected on the passenger seat, the airbag will deploy at full force, depending on the severity of the crash, speed of the vehicle, and other factors which may result in the airbag deploying at a reduced force.
SEE FIGURE 60–20.
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FIGURE 60–22 A resistor-type occupant detection sensor. The weight of the passenger strains these resistors, which are attached to the seat, thereby signaling to the module the weight of the occupant.
FIGURE 60–20 The passenger side airbag “on” lamp will light if a passenger is detected on the passenger seat.
FIGURE 60–23 A test weight is used to calibrate the occupant detection system on a Chrysler vehicle.
FIGURE 60–21 A gel-filled (bladder-type) occupant detection sensor showing the pressure sensor and wiring.
CAUTION: Because the resistors are part of the seat structure, it is very important that all seat fasteners be torqued to factory specifications to ensure proper operation of the occupant detection system. A seat track position (STP) sensor is used by the airbag controller to determine the position of the seat. If the seat is too close to the airbag, the controller may disable the airbag.
TYPE OF SEAT SENSOR
DIAGNOSING OCCUPANT DETECTION SYSTEMS
The passenger presence system (PPS) uses one of three types of sensors.
Gel-filled bladder sensor. This type of occupant sensor uses a silicone-filled bag that has a pressure sensor attached. The weight of the passenger is measured by the pressure sensor, which sends a voltage signal to the module controlling the airbag deployment. A safety belt tension sensor is also used with a gel-filled bladder system to monitor the tension on the belt. The module then uses the information from both the bladder and the seat belt sensor to determine if a tightened belt may be used to restrain a child seat. SEE FIGURE 60–21.
Capacitive strip sensors. This type of occupant sensor uses several flexible conductive metal strips under the seat cushion. These sensor strips transmit and receive a low-level electric field, which changes due to the weight of the front passenger seat occupant. The module determines the weight of the occupant based on the sensor values.
Force-sensing resistor sensors. This type of occupant sensor uses resistors, which change their resistance based on the stress that is applied. These resistors are part of the seat structure, and the module can determine the weight of the occupant based on the change in the resistance of the sensors. SEE FIGURE 60–22.
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A fault in the system may cause the passenger side airbag light to turn on when there is no weight on the seat. A scan tool is often used to check or calibrate the seat, which must be empty, by commanding the module to rezero the seat sensor. Some systems, such as those on Chrysler vehicles, use a unit that has various weights along with a scan tool to calibrate and diagnose the occupant detection system. SEE FIGURE 60–23.
SEAT AND SIDE CURTAIN AIRBAGS SEAT AIRBAGS
Side and/or curtain airbags use a variety of sensors to determine if they need to be deployed. Side airbags are mounted in one of two general locations.
In the side bolster of the seat ( SEE FIGURE 60–24.)
In the door panel
Most side airbag sensors use an electronic accelerometer to detect when to deploy the airbags, which are usually mounted to the
EVENT DATA RECORDERS PARTS AND OPERATION
As part of the airbag controller on many vehicles, the event data recorder (EDR) is used to record parameters just before and slightly after an airbag deployment. The following parameters are recorded.
FIGURE 60–24 A typical seat (side) airbag that deploys from the side of the seat.
TECH TIP Aggressive Driving and OnStar If a vehicle equipped with the OnStar system is being driven aggressively and the electronic stability control system has to intercede to keep the vehicle under control, OnStar may call the vehicle to see if there has been an accident. The need for a call from OnStar usually will be determined if the accelerometer registers slightly over 1 g-force, which could be achieved while driving on a race track.
Vehicle speed
Brake on/off
Seat belt fastened
G-forces as measured by the accelerometer
Unlike an airplane event data recorder, a vehicle unit is not a separate unit and does not record voice conversations and does not include all crash parameters. This means that additional crash data, such as skid marks and physical evidence at the crash site, will be needed to fully reconstruct the incident. The EDR is embedded into the airbag controller and receives data from many sources and at varying sample rates. The data is constantly being stored in a memory buffer and not recorded into the EPROM unless an airbag deployment has been commanded. The combined data is known as an event file. The airbag is commanded on, based on input mainly from the accelerometer sensor. This sensor, usually built into the airbag controller, is located inside the vehicle. The accelerometer calculates the rate of change of the speed of the vehicle. This determines the acceleration rate and is used to predict if that rate is high enough to deploy the frontal airbags. The airbags will be deployed if the threshold g-value is exceeded. The passenger side airbag will also be deployed unless it is suppressed by either of the following:
No passenger is detected.
The passenger side airbag switch is off.
DATA EXTRACTION bottom of the left and right “B” pillars (where the front doors latch) behind a trim panel on the inside of the vehicle. CAUTION: Avoid using a lockout tool (e.g., a “slim jim”) in vehicles equipped with side airbags to help prevent damage to the components and wiring in the system.
SIDE CURTAIN AIRBAGS
Side curtain airbags are usually deployed by a module based on input from many different sensors, including a lateral acceleration sensor and wheel speed sensors. For example, in one system used by Ford, the ABS controller commands that the brakes on one side of the vehicle be applied, using down pressure while monitoring the wheel speed sensors. If the wheels slow down with little brake pressure, the controller assumes that the vehicle could roll over, thereby deploying the side curtain airbags.
Data extraction from the event data recorder in the airbag controller can only be achieved using a piece of equipment known as the Crash Data Retrieval System, manufactured by Vetronics Corporation. This is the only authorized method for retrieving event files and only certain organizations are allowed access to the data. These groups or organizations include:
Original equipment manufacturer’s representatives
National Highway Traffic Safety Administration
Law enforcement agencies
Accident reconstruction companies
Crash data retrieval must only be done by a trained crash data retrieval (CDR) technician or analyst. A technician undergoes specialized training and must pass an examination. An analyst must attend additional training beyond that of a technician to achieve CDR analyst certification.
REVIEW QUESTIONS 1. What are the safety precautions to follow when working around an airbag?
3. How should deployed inflation modules be handled? 4. What is the purpose of pretensioners?
2. What sensor(s) must be triggered for an airbag deployment?
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CHAPTER QUIZ 1. A vehicle is being repaired after an airbag deployment. Technician A says that the inflator module should be handled as if it is still live. Technician B says rubber gloves should be worn to prevent skin irritation. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 2. A seat belt pretensioner is ________. a. A device that contains an explosive charge b. Used to remove slack from the seat belt in the event of a collision c. Used to force the occupant back into position against the seat back in the event of a collision d. All of the above 3. What conducts power and ground to the driver’s side airbag? a. Twisted-pair wires b. Clockspring c. Carbon contact and brass surface plate on the steering column d. Magnetic reed switch 4. Two technicians are discussing dual-stage airbags. Technician A says that a deployed airbag is safe to handle regardless of which stage caused the deployment of the airbag. Technician B says that both stages ignite, but at different speeds depending on the speed of the vehicle. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
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5. Where are shorting bars used? a. In pretensioners b. At the connectors for airbags c. In the crash sensors d. In the airbag controller 6. Technician A says that a deployed airbag can be repacked, reused, and reinstalled in the vehicle. Technician B says that a deployed airbag should be discarded and replaced with an entire new assembly. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 7. What color are the airbag electrical connectors and conduit? a. Blue c. Yellow b. Red d. Orange 8. Driver and/or passenger front airbags will only deploy if a collision occurs how many degrees from straight ahead? a. 10 degrees c. 60 degrees b. 30 degrees d. 90 degrees 9. How many sensors must be triggered at the same time to cause an airbag deployment? a. One c. Three b. Two d. Four 10. The electrical terminals used for airbag systems are unique because they are ________. a. Solid copper b. Tin-plated heavy-gauge steel c. Silver plated d. Gold plated
AUDIO SYSTEM OPERATION AND DIAGNOSIS
OBJECTIVES: After studying Chapter 61, the reader will be able to: • Prepare for ASE Electrical/Electronic Systems (A6) certification test content area “H” (Accessories Diagnosis and Repair). • Describe how AM and FM radio works. • Explain how to test speaker polarity. • Explain how to match speaker impedance. • Explain how crossovers work. • Describe how satellite radio works • Explain how Bluetooth systems work • Discuss voice recognition systems. • List causes and corrections of radio noise and interference. KEY TERMS: Active crossover 705 • Alternator whine 708 • AM 699 • Bluetooth 707 • Crossover 704 • Decibels (dB) 704 • Floating ground system 704 • FM 699 • Frequency 699 • Ground plane 701 • Hertz 699 • High-pass filter 705 • Impedance 702 • Low-pass filter 705 • Modulation 699 • Powerline capacitor 705 • Radio choke 709 • Radio frequency (RF) 699 • RMS 706 • SDARS 707 • Skin effect 703 • Speakers 702 • Stiffening capacitor 705 • Subwoofer 704 • THD 706 • Tweeter 704 • Voice recognition 706 • Wavelength 699
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AUDIO FUNDAMENTALS INTRODUCTION
The audio system of today’s vehicles is a complex combination of antenna system, receiver, amplifier, and speakers all designed to provide living room–type music reproduction while the vehicle is traveling in city traffic or at highway speed. Audio systems produce audible sounds and include:
Radio (AM, FM, and satellite)
Antenna systems that are used to capture electronic energy broadcast to radios
Speaker systems
Aftermarket enhancement devices that increase the sound energy output of an audio system
Diagnosis of audio-related problems
Many audio-related problems can be addressed and repaired by a service technician.
TYPES OF ENERGY
There are two types of energy that affect
audio systems.
Electromagnetic energy or radio waves. Antennas capture the radio waves which are then sent to the radio or receiver to be amplified.
Acoustical energy, usually called sound. Radios and receivers amplify the radio wave signals and drive speakers which reproduce the original sound as transmitted by radio waves.
wavelengths per second, and megahertz (MHz), millions of wavelengths per second. SEE FIGURE 61–2.
The higher the frequency, the shorter the wavelength.
The lower the frequency, the longer the wavelength.
A longer wavelength can travel a farther distance than a shorter wavelength. Therefore, lower frequencies provide better reception at farther distances.
AM radio frequencies range from 530 to 1,710 kHz.
FM radio frequencies range from 87.9 to 107.9 MHz.
MODULATION
Modulation is the term used to describe when information is added to a constant frequency. The base radio frequency used for RF is called the carrier wave. A carrier is a radio wave that is changed to carry information. The two types of modulation are:
Amplitude modulation (AM)
Frequency modulation (FM)
AM waves are radio waves that have amplitude that can be varied, transmitted, and detected by a receiver. Amplitude is the height of the wave as graphed on an oscilloscope. SEE FIGURE 61–3. FM waves are also radio waves that have a frequency that can be varied, transmitted, and detected by a receiver. This type of modulation changes the number of cycles per second, or frequency, to carry the information. SEE FIGURE 61–4. WAVELENGTH
SEE FIGURE 61–1. Radio waves travel at approximately the speed of light (186,282,000 miles per second) and are electromagnetic. Radio waves are measured in two ways, wavelength and frequency. A radio wave has a series of high points and low points. A wavelength is the time and distance between two consecutive points, either high or low. A wavelength is measured in meters. Frequency, also known as radio frequency (RF), is the number of times a particular waveform repeats itself in a given amount of time, and is measured in hertz (Hz). A signal with a frequency of 1 Hz is one radio wavelength per second. Radio frequencies are measured in kilohertz (kHz), thousands of
AMPLITUDE
TERMINOLOGY
ELECTROMAGNETIC RADIO WAVES
TIME (FREQUENCY)
FIGURE 61–2 The relationship among wavelength, frequency, and amplitude.
ACOUSTICAL SOUND WAVES
FIGURE 61–1 Audio systems use both electromagnetic radio waves and sound waves to reproduce sound inside the vehicle.
AM WAVES
FIGURE 61–3 The amplitude changes in AM broadcasting.
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AM CHARACTERISTICS
AM radio reception can be achieved over long distances from the transmitter because the waves can bounce off the ionosphere, usually at night. Even during the day, the AM signals can be picked up some distance from the transmitter. AM radio reception depends on a good antenna. If there is a fault in the antenna circuit, AM reception is affected the most.
FM WAVES
FIGURE 61–4 The frequency changes in FM broadcasting and the amplitude remains constant.
LOWER SIDEBAND
TUNED FREQUENCY
UPPER SIDEBAND
FM CHARACTERISTICS
Because FM waves have a high RF and a short wavelength, they travel only a short distance. The waves cannot follow the shape of the earth but instead travel in a straight line from the transmitter to the receiver. FM waves will travel through the ionosphere and into space and do not reflect back to earth like AM waves.
MULTIPATH
-100K HZ
CENTER
+100K HZ
Multipath is caused by reflected, refracted, or line of sight signals reaching an antenna at different times. Multipath results from the radio receiving two signals to process on the same frequency. This causes an echo effect in the speakers. Flutter, or picket fencing as it is sometimes called, is caused by the blocking of part of the FM signal. This blocking causes a weakening of the signal resulting in only part of the signal getting to the antenna, causing an on-again off-again radio sound. Flutter also occurs when the transmitter and the receiving antenna are far apart.
FIGURE 61–5 Using upper and lower sidebands allows stereo to be broadcast. The receiver separates the signals to provide left and right channels.
RADIOS AND RECEIVERS
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FREQUENTLY ASKED QUESTION
What Does a “Capture” Problem Mean? A capture problem affects only FM reception and means that the receiver is playing more than one station if two stations are broadcasting at the same frequency. Most radios capture the stronger signal and block the weaker signal. However, if the stronger signal is weakened due to being blocked by buildings or mountains, the weaker signal will then be used. When this occurs, it will sound as if the radio is changing stations by itself. This is not a fault with the radio, but simply a rare occurrence with FM radio.
The antenna receives the radio wave where it is converted into very weak fluctuating electrical current. This current travels along the antenna lead-in to the radio that amplifies the signal and sends the new signal to the speakers where it is converted into acoustical energy. Most late-model radios and receivers use five input/output circuits. 1. Power. Usually a constant 12 volt feed to keep the internal clock alive 2. Ground. This is the lowest voltage in the circuit and connects indirectly to the negative terminal of the battery. 3. Serial data. Used to turn the unit on and off and provide other functions such as steering wheel control operation 4. Antenna input. From one or more antennas
RADIO WAVE TRANSMISSION
More than one signal can be carried by a radio wave. This process is called sideband operation. Sideband frequencies are measured in kilohertz. The amount of the signal above the assigned frequency is referred to as the upper sideband. The amount of the signal below the assigned frequency is called the lower sideband. This capability allows radio signals to carry stereo broadcasts. Stereo broadcasts use the upper sideband to carry one channel of the stereo signal, and the lower sideband to carry the other channel. When the signal is decoded by the radio, these two signals become the right and left channels. SEE FIGURE 61–5.
NOISE Because radio waves are a form of electromagnetic energy, other forms of energy can impact them. For example, a bolt of lightning generates broad radio-frequency bandwidths known as radio-frequency interference (RFI). RFI is one type of electromagnetic interference (EMI) and is the frequency that interferes with radio transmission.
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5. Speaker outputs. These wires connect the receiver to the speakers or as an input to an amplifier.
ANTENNAS TYPES OF ANTENNAS
The typical radio electromagnetic energy from the broadcast antenna induces a signal in the antenna that is very small, only about 25 microvolts AC (0.000025 VAC) in strength. The radio contains amplifier circuits that increase the received signal strength into usable information. For example, the five types of antennas used on vehicles include:
Slot antenna. The slot antenna is concealed in the roof of some plastic body vehicles such as older General Motors plastic body vans. This antenna is surrounded by metal on a Mylar sheet.
FOIL (SLOT) ANTENNA USED ON PLASTIC BODY VEHICLE BETWEEN HEADLINER AND ROOF
MAST = 1/4 WAVELENGTH BODY OF VEHICLE ONE WAVE LENGTH
SLOT ANTENNA
REAR WINDOW DEFOGGER GRID
BODY = 1/4 WAVELENGTH
FIGURE 61–7 The ground plane is actually one-half of the antenna.
POWER MAST
INTEGRATED ANTENNA
FIXED MAST
FIGURE 61–6 The five types of antennas used on General Motors vehicles include the slot antenna, fixed mast antenna, rear window defogger grid antenna, a powered mast antenna, and an integrated antenna.
Rear window defogger grid. This type of system uses the heating wires to receive the signals and special circuitry to separate the RF from the DC heater circuit.
Powered mast. These antennas are controlled by the radio. When the radio is turned on, the antenna is raised; when the radio is shut off, the antenna is retracted. The antenna system consists of an antenna mast and a drive motor controlled by the radio “on” signal through a relay.
Fixed mast antenna. This antenna offers the best overall performance currently available. The mast is simply a vertical rod. Mast antennas are typically located on the fender or rear quarter panel of the vehicle.
Integrated antenna. This type of antenna is sandwiched in the windshield and an appliqué on the rear window glass. The antenna in the rear window is the primary antenna and receives both AM and FM signals. The secondary antenna is located in the front windshield typically on the passenger side of the vehicle. This antenna receives only FM signals.
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FREQUENTLY ASKED QUESTION
What Is a Ground Plane? Antennas designed to pick up the electromagnetic energy that is broadcast through the air to the transmitting antenna are usually one-half wavelength high, and the other half of the wavelength is the ground plane. This one-half wavelength in the ground plane is literally underground. For ideal reception, the receiving antenna should also be the same as the wavelength of the signal. Because this length is not practical, a design compromise uses the length of the antenna as one-fourth of the wavelength; in addition, the body of the vehicle itself is one-fourth of the wavelength. The body of the vehicle, therefore, becomes the ground plane. SEE FIGURE 61–7. Any faulty condition in the ground plane circuit will cause the ground plane to lose effectiveness, such as: • • • • •
Loose or corroded battery cable terminals Acid buildup on battery cables Engine grounds with high resistance Loss of antenna or audio system grounds Defective alternator, causing an AC ripple exceeding 50 mV (0.050 V)
SEE FIGURE 61–6.
ANTENNA TESTING
ANTENNA DIAGNOSIS ANTENNA HEIGHT
The antenna collects all radio-frequency signals. An AM radio operates best with as long an antenna as possible, but FM reception is best when the antenna height is exactly 31 in. (79 cm). Most fixed-length antennas are, therefore, exactly this height. Even the horizontal section of a windshield antenna is 31 in. (79 cm) long. A defective antenna will:
Greatly affect AM radio reception
May affect FM radio reception
If the antenna or lead-in cable is broken (open), FM reception will be heard but may be weak, and there will be no AM reception. An ohmmeter should read infinity between the center antenna lead and the antenna case. For proper reception and lack of noise, the case of the antenna must be properly grounded to the vehicle body. SEE FIGURE 61–8.
POWER ANTENNA TESTING AND SERVICE
Most power antennas use a circuit breaker and a relay to power a reversible, permanent magnet (PM) electric motor that moves a nylon cord attached to the antenna mast. Some vehicles have a dash-mounted control that can regulate antenna mast height and/or operation, whereas many operate automatically when the radio is turned on and off. The power antenna assembly is usually mounted between the outer and inner front fender or in the rear quarter panel. The unit contains the motor, a spool for the cord, and upper- and lower-limit
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LESS THAN 5
LESS THAN 5
MUST BE INFINITY
FIGURE 61–8 If all ohmmeter readings are satisfactory, the antenna is good.
TECH TIP
FIGURE 61–9 Cutting a small hole in a fender cover helps to protect the vehicle when replacing or servicing an antenna.
The Hole in the Fender Cover Trick A common repair is to replace the mast of a power antenna. To help prevent the possibility of causing damage to the body or paint of the vehicle, cut a hole in a fender cover and place it over the antenna. SEE FIGURE 61–9. If a wrench or tool slips during the removal or installation process, the body of the vehicle will be protected.
switches. The power antenna mast is tested in the same way as a fixed-mast antenna. (An infinity reading should be noted on an ohmmeter when the antenna is tested between the center antenna terminal and the housing or ground.) Except in the case of cleaning or mast replacement, most power antennas are either replaced as a unit or repaired by specialty shops. SEE FIGURE 61–10. Making certain that the drain holes in the motor housing are not plugged with undercoating, leaves, or dirt can prevent many power antenna problems. All power antennas should be kept clean by wiping the mast with a soft cloth and lightly oiling with light oil such as WD-40 or similar.
FIGURE 61–10 A typical power antenna assembly. Note the braided ground wire used to ensure that the antenna has a good ground plane.
Good-quality speakers are the key to a proper sounding radio or sound system. Replacement speakers should be securely mounted and wired according to the correct polarity. SEE FIGURE 61–12.
IMPEDANCE MATCHING
SPEAKERS PURPOSE AND FUNCTION
The purpose of any speaker is to reproduce the original sound as accurately as possible. Speakers are also called loudspeakers. The human ear is capable of hearing sounds from a very low frequency of 20 Hz (cycles per seconds) to as high as 20,000 Hz. No one speaker is capable of reproducing sound over such a wide frequency range. SEE FIGURE 61–11.
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All speakers used on the same radio or amplifier should have the same internal coil resistance, called impedance. If unequal-impedance speakers are used, sound quality may be reduced and serious damage to the radio may result. SEE FIGURE 61–13. All speakers should have the same impedance. For example, if two 4 ohm speakers are being used for the rear and they are connected in parallel, the total impedance is 2 ohms. RT
4 (impedance of each speaker) 2 ohms 2 (number of speakers in parallel)
6V - 7VDC AUDIO AMPLIFIER
6V - 7VDC
4- SPEAKER
8- TOTAL IMPEDANCE
CONE MOVING IN
6V - 7VDC
4- SPEAKER
AUDIO AMPLIFIER (a) 6V - 7VDC CONE MOVING OUT
FIGURE 61–11 Between 6 and 7 volts is applied to each speaker terminal, and the audio amplifier then increases the voltage on one terminal and at the same time decreases the voltage on the other terminal causing the speaker cone to move. The moving cone then moves the air, causing sound.
2- TOTAL IMPEDANCE
4- SPEAKER
4- SPEAKER
(b)
FIGURE 61–13 (a) Two 4 ohm speakers connected in series result in total impedance of 8 ohms. (b) Two 4 ohm speakers connected in parallel result in total impedance of 2 ohms.
TECH TIP Skin Effect
FIGURE 61–12 A typical automotive speaker with two terminals. The polarity of the speakers can be identified by looking at the wiring diagram in the service manual or by using a 1.5 volt battery to check. When the battery positive is applied to the positive terminal of the speaker, the cone will move outward. When the battery leads are reversed, the speaker cone will move inward.
When a high-frequency signal (AC voltage) is transmitted through a wire, the majority of it travels on the outside surface of the wire. This characteristic is called skin effect. The higher the frequency is, the closer to the outer surface the signal moves. To increase audio system output, most experts recommend the use of wire that has many strands of very fine wire to increase the surface area or the skin area of the conductor. Therefore, most aftermarket speaker wire is stranded with many smalldiameter copper strands.
The front speakers should also represent a 2 ohm load from the radio or amplifier. See the following example. Two front speakers: each 2 ohms Two rear speakers: each 8 ohms Solution: Connect the front speakers in series (connect the positive [⫹] of one speaker to the negative [⫺] of the other) for a total impedance of 4 ohms (2 Ω ⫹ 2 Ω ⫽ 4 Ω). Connect the two rear speakers in parallel (connect the positive [⫹] of each speaker together and the negative [⫺] of each speaker together) for a total impedance of 4 ohms (8 Ω ⫼ 2 ⫽ 4 Ω).
SPEAKER WIRING
The wire used for speakers should be as large a wire (as low an AWG gauge number) as is practical in order to be assured that full power is reaching the speakers. Typical “speaker wire” is about 22 gauge (0.35 mm2), yet tests conducted by audio engineers have concluded that increasing the wire gauge—up to 4 gauge (19 mm2) or larger—greatly increases sound quality. All wiring connections should be soldered after making certain that all speaker connections have the correct polarity.
AUDIO SYSTEM OPERATION AND DIAGNOSIS
703
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CAUTION: Be careful when installing additional audio equipment on a General Motors vehicle system that uses a twowire speaker connection called a floating ground system. Other systems run only one power (hot) lead to each speaker and ground the other speaker lead to the body of the vehicle.
What Is a Bass Blocker? A bass blocker is a capacitor and coil assembly that effectively blocks low frequencies. A bass blocker is normally used to block low frequencies being sent to the smaller front speakers. Using a bass blocker allows the smaller front speakers to more efficiently reproduce the midrange and high-range frequency sounds.
This arrangement helps prevent interference and static that could occur if these components were connected to a chassis (vehicle) ground. If the components are chassis grounded, there may be a difference in the voltage potential (voltage); this condition is called a ground loop. CAUTION: Regardless of radio speaker connections used, never operate any radio without the speakers connected, or the speaker driver section of the radio may be damaged as a result of the open speaker circuit.
SPEAKER TYPES INTRODUCTION No one speaker is capable of reproducing sound over such a wide frequency range. Therefore, speakers are available in three basic types. 1. Tweeters are for high-frequency ranges.
FREQUENTLY ASKED QUESTION
between 100 and 500 Hz. Low-frequency sounds from these speakers are not directional. This means that the listener usually cannot detect the source of the sound from these speakers. The lowfrequency sounds seem to be everywhere in the vehicle, so the location of the speakers is not as critical as with the higher frequency speakers. The subwoofer can be placed almost anywhere in the vehicle. Most subwoofers are mounted in the rear of the vehicle where there is more room for the larger subwoofer speakers.
SPEAKER FREQUENCY RESPONSE
Frequency response is how a speaker responds to a range of frequencies. A typical frequency response for a midrange speaker may be 500 to 4,000 Hz.
2. Midrange are for mid-frequency ranges. 3. Woofers and subwoofers are for low-frequency ranges.
SOUND LEVELS WARNING Hearing loss is possible if exposed to loud sounds. According to noise experts (audiologists), hearing protection should be used whenever the following occurs. 1. You must raise your voice to be heard by others next to you. 2. You cannot hear someone else speaking who is less than 3 ft (1 m) away. 3. You are operating power equipment, such as a lawnmower.
DECIBEL SCALE
A decibel (dB) is a measure of sound power, and it is the faintest sound a human can hear in the midband frequencies. The dB scale is not linear (straight line) but logarithmic, meaning that a small change in the dB reading results in a large change in volume of noise. An increase of 10 dB in sound pressure is equal to doubling the perceived volume. Therefore, a small difference in dB rating means a big difference in the sound volume of the speaker.
EXAMPLES
Some examples of decibel sound levels include:
Quiet, faint
30 dB: whisper, quiet library 40 dB: quiet room
TWEETER
A tweeter is a speaker designed to reproduce highfrequency sounds, usually between 4,000 and 20,000 Hz (4 and 20 kHz). Tweeters are very directional. This means that the human ear is most likely to be able to detect the location of the speaker while listening to music. This also means that a tweeter should be mounted in the vehicle where the sound can be directed in line of sight to the listener. Tweeters are usually mounted on the inside door near the top, windshield “A” pillar, or similar locations.
Moderate
50 dB: moderate range sound 60 dB: normal conversation
Loud
70 dB: vacuum cleaner, city traffic 80 dB: busy noisy traffic, vacuum cleaner
Extremely loud
Hearing loss possible
90 dB: lawnmower, shop tools 100 dB: chain saw, air drill 110 dB: loud rock music
MIDRANGE
A midrange speaker is designed and manufactured to be able to best reproduce sounds in the middle of the human hearing range, from 400 to 5,000 Hz. Most people are sensitive to the sound produced by these midrange speakers. These speakers are also directional in that the listener can usually locate the source of the sound.
CROSSOVERS DEFINITION
SUBWOOFER
A subwoofer, sometimes called a woofer, produces the lowest frequency of sounds, usually 125 Hz and lower. A midbass speaker may also be used to reproduce those frequencies
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A crossover is designed to separate the frequency of a sound and send a certain frequency range, such as low bass sounds, to a woofer designed to reproduce these low-frequency sounds. There are two types of crossovers: passive and active.
WOOFER (50 - 5K HZ)
CROSSOVER CIRCUIT
POWERLINE (STIFFENING) CAPACITORS
AUDIO AMPLIFIER
CAPACITOR (3.3F -10F)
TWEETER (4K - 20K HZ)
FIGURE 61–14 Crossovers are used in audio systems to send high-frequency sounds to the small (tweeter) speakers and lowfrequency sounds to larger (woofer) speakers.
FIGURE 61–15 Two capacitors connected in parallel provide the necessary current flow to power large subwoofer speakers.
POWERLINE CAPACITOR USAGE GUIDE
PASSIVE CROSSOVER
A passive crossover does not use an external power source. Rather it uses a coil and a capacitor to block certain frequencies that a particular type of speaker cannot handle and allow just those frequencies that it can handle to be applied to the speaker. For example, a 6.6 millihenry coil and a 200 microfarad capacitor can effectively pass 100 Hz frequency sound to a large 10 in. subwoofer. This type of passive crossover is called a low-pass filter, because it passes (transfers) only the low-frequency sounds to the speaker and blocks all other frequencies. A high-pass filter is used to transfer higher frequency (over 100 Hz) to smaller speakers.
WATTS (AMPLIFIER)
RECOMMENDED CAPACITOR IN FARADS (MICROFARADS)
100 W
0.10 farad (100,000 μF)
200 W
0.20 farad (200,000 μF)
250 W
0.25 farad (250,000 μF)
500 W
0.50 farad (500,000 μF)
750 W
0.75 farad (750,000 μF)
1,000 W
1.00 farad (1,000,000 μF)
ACTIVE CROSSOVER
Active crossovers use an external power source and produce superior performance. An active crossover is also called an electronic crossover or crossover network. These units include many powered filters and are considerably more expensive than passive crossovers. Two amplifiers are necessary to fully benefit from an active crossover. One amplifier is for the higher frequencies and midrange and the other amplifier is for the subwoofers. If you are on a budget and plan to use just one amplifier, then use passive crossover. If you can afford to use two or more amplifiers, then consider using the electronic (active) crossover. SEE FIGURE 61–14 for an example of crossovers used in factoryinstalled systems.
AFTERMARKET SOUND SYSTEM UPGRADE POWER AND GROUND UPGRADES
If adding an amplifier and additional audio components, be sure to include the needed power and ground connections. These upgrades can include:
A separate battery for the audio system
An inline fuse near the battery to protect the wiring and the components
Wiring that is properly sized to the amperage draw of the system and the length of wire (The higher the output wattage the
CHART 61–1 The rating of the capacitor needed to upgrade an audio system is directly related to the wattage of the system. greater the amperage required and the larger the wire gauge needed. The longer the distance between the battery and the components, the larger the wire gauge needed for best performance.)
Ground wires at least the same gauge as the power side wiring (Some experts recommend using extra ground wires for best performance.)
Read, understand, and follow all instructions that come with audio system components.
POWERLINE CAPACITOR A powerline capacitor, also called a stiffening capacitor, refers to a large capacitor (often abbreviated CAP) of 0.25 farad or larger connected to an amplifier power wire. The purpose and function of this capacitor is to provide the electrical reserve energy needed by the amplifier to provide deep bass notes. SEE FIGURE 61–15. Battery power is often slow to respond; and when the amplifier attempts to draw a large amount of current, the capacitor will try to stabilize the voltage level at the amplifier by discharging stored current as needed. A rule of thumb is to connect a capacitor with a capacity of 1 farad for each 1,000 watts of amplifier power. SEE CHART 61–1.
AUDIO SYSTEM OPERATION AND DIAGNOSIS
705
FUSE
AMPLIFIER
BATTERY CAPACITOR
FIGURE 61–16 A powerline capacitor should be connected through the power wire to the amplifier as shown. When the amplifier requires more electrical power (watts) than the battery can supply, the capacitor will discharge into the amplifier and supply the necessary current for the fraction of a second it is needed by the amplifier. At other times when the capacitor is not needed, it draws current from the battery to keep it charged.
FIGURE 61–17 Voice commands can be used to control many functions, including navigation systems, climate control, telephone, and radio.
CAPACITOR INSTALLATION
A powerline capacitor connects to the power leads between the inline fuse and the amplifier. SEE FIGURE 61–16. If the capacitor were connected to the circuit as shown without “precharging,” the capacitor would draw so much current that it would blow the inline fuse. To safely connect a large capacitor, it must be precharged. To precharge the capacitor, follow these steps. STEP 1
Connect the negative (⫺) terminal of the capacitor to a good chassis ground.
STEP 2
Insert an automotive 12 V light bulb, such as a headlight or parking light, between the positive (⫹) terminal of the capacitor and the positive terminal of the battery. The light will light as the capacitor is being charged and then go out when the capacitor is fully charged.
STEP 3
Disconnect the light from the capacitor, then connect the power lead to the capacitor. The capacitor is now fully charged and ready to provide the extra power necessary to supplement battery power to the amplifier.
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FREQUENTLY ASKED QUESTION
What Do the Amplifier Specifications Mean? RMS power
RMS means root-mean-square and is the rating that indicates how much power the amplifier is capable of producing continuously.
RMS power at 2 ohms
This specification in watts indicates how much power the amplifier delivers into a 2 ohm speaker load. This 2 ohm load is achieved by wiring two 4 ohm speakers in parallel or by using 2 ohm speakers.
Peak power
Peak power is the maximum wattage an amplifier can deliver in a short burst during a musical peak.
THD
Total harmonic distortion (THD) represents the amount of change of the signal as it is being amplified. The lower the number, the better the amplifier (e.g., a 0.01% rating is better than a 0.07% rating).
Signal-tonoise ratio
This specification is measured in decibels (dB) and compares the strength of the signal with the level of the background noise (hiss). A higher volume indicates less background noise (e.g., a 105 dB rating is better than a 100 dB rating).
VOICE RECOGNITION PARTS AND OPERATION
Voice recognition is an expanding technology. It allows the driver of a vehicle to perform tasks, such as locate an address in a navigation system by using voice commands rather than buttons. In the past, users had to say the exact words to make it work such as the following examples listed from an owner manual for a vehicle equipped with a voice-actuated navigation system. “Go home” “Repeat guidance” “Nearest ATM” The problem with these simple voice commands was that the exact wording had to be spoken. The voice recognition software would compare the voice command to a specific list of words or phrases stored in the system in order for a match to occur. Newer systems recognize speech patterns and take action based on learned patterns. Voice recognition can be used for the following functions. 1. Navigation system operation ( SEE FIGURE 61–17.) 2. Sound system operation 3. Climate control system operation 4. Telephone dialing and other related functions ( SEE FIGURE 61–18.)
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A microphone is usually placed in the driver’s side sun visor or in the overhead console in the center top portion of the windshield area.
DIAGNOSIS AND SERVICE
Voice recognition is usually incorporated into many functions of the vehicle. If a problem occurs with the system, perform the following steps. 1. Verify the customer complaint (concern). Check the owner manual or service information for the proper voice commands and verify that the system is not functioning correctly.
VOICE ICON
FIGURE 61–18 The voice command icon on the steering wheel of a Cadillac.
2. Check for any aftermarket accessories that may interfere or were converted to components used by the voice recognition system, such as remote start units, MP3 players, or any other electrical component. 3. Check for stored diagnostic trouble codes (DTCs) using a scan tool. 4. Follow the recommended troubleshooting procedures as stated in service information.
BLUETOOTH OPERATION
Bluetooth is a (radio frequency) standard for short-range communications. The range of a typical Bluetooth device is 33 ft (10 m) and it operates in the ISM (industrial, scientific, and medical) band between 2.4000 and 2.4835 MHz. Bluetooth is a wireless standard that works on two levels.
It provides physical communication using low power, requiring only about 1 milliwatt (1/1,000 of a watt) of electrical power, making it suitable for use with small handheld or portable devices, such as an ear-mounted speaker/microphone.
It provides a standard protocol for how bits of data are sent and received.
The Bluetooth standard is an advantage because it is wireless, low cost, and automatic. The automotive use of Bluetooth technology is in the operation of a cellular telephone being tied into the vehicle. The vehicle allows the use of hands-free telephone usage. A vehicle that is Bluetooth telephone equipped has the following components.
A Bluetooth receiver can be built into the navigation or existing sound system.
A microphone allows the driver to use voice commands as well as telephone conversations from the vehicle to the cell via Bluetooth wireless connections.
Many cell phones are equipped with Bluetooth which may allow the caller to use an ear-mounted microphone and speaker. SEE FIGURE 61–19. If the vehicle and the cell phone are equipped with Bluetooth, the speaker and microphone can be used as a hands-free telephone when the phone is in the vehicle. The cell phone can be activated in the vehicle by using voice commands.
FIGURE 61–19 Bluetooth earpiece that contains a microphone and speaker unit that is paired to a cellular phone. The telephone has to be within 33 ft (10 m) of the earpiece.
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FREQUENTLY ASKED QUESTION
Where Did Bluetooth Get Its Name? The early adopters of the standard used the term Bluetooth, and they named it for Harold Bluetooth, the king of Denmark in the late 900s. The king was able to unite Denmark and part of Norway into a single kingdom.
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FREQUENTLY ASKED QUESTION
Can Two Bluetooth Telephones Be Used in a Vehicle? Usually. In order to use two telephones, the second phone needs to be given a name. When both telephones enter the vehicle, check which one is recognized. Say “phone status” and the system will tell you to which telephone the system is responding. If it is not the one you want, simply say, “next phone” and it will move to the other one.
SATELLITE RADIO PARTS AND OPERATION
Satellite radio, also called Satellite Digital Audio Radio Services or SDARS, is a fee-based system that uses satellites to broadcast high-quality radio. SDARS broadcasts on the S-band of 2.1320 to 2.345 GHz.
SIRIUS/XM RADIO
Sirius/XM radio is standard equipment or optional in most vehicles. XM radio uses two satellites launched in 2001 called Rock (XM-2) and Roll (XM-1) in a geosynchronous orbit above North America. Two replacement satellites, Rhythm (XM-3) and Blues (XM-4) were launched in 2006. Sirius and XM radio combined in 2008 and now share some programming. The two types of satellite radios use different protocols and, therefore, require separate radios unless a combination unit is purchased.
AUDIO SYSTEM OPERATION AND DIAGNOSIS
707
AREA COVERED BY SINGLE FREQUENCY NETWORK
WEST SATELLITE
EAST SATELLITE
REPEATER #1 REPEATER #2
FIGURE 61–20 SDARS uses satellites and repeater stations to broadcast radio.
FIGURE 61–21 An aftermarket XM radio antenna mounted on the rear deck lid. The deck lid acts as the ground plane for the antenna.
FIGURE 61–22 A shark-fin-type factory antenna used for both XM and OnStar.
RECEPTION
recommended procedures. Check the following websites for additional information.
Reception from satellites can be affected by tall buildings and mountains. To help ensure consistent reception, both SDARS providers do the following:
Include in the radio itself a buffer circuit that can store several seconds of broadcasts to provide service when traveling out of a service area
www.xmradio.com
www.sirius.com
www.siriusxm.com
Provide land-based repeater stations in most cities ( SEE FIGURE 61–20.)
ANTENNA
To be able to receive satellite radio, the antenna needs to be able to receive signals from both the satellite and the repeater stations located in many large cities. There are various types and shapes of antennas, including those shown in FIGURES 61–21 AND 61–22.
DIAGNOSIS AND SERVICE
The first step in any diagnosis is to verify the customer complaint (concern). If no satellite service is being received, first check with the customer to verify that the monthly service fee has been paid and the account is up to date. If poor reception is the cause, carefully check the antenna for damage or faults with the lead-in wire. The antennas must be installed on a metal surface to provide the proper ground plane. For all other satellite radio fault problems, check service information for the exact tests and procedures. Always follow the factory
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RADIO INTERFERENCE DEFINITION
Radio interference is caused by variations in voltage in the powerline or picked up by the antenna. A “whine” that increases in frequency with increasing engine speed is usually referred to as an alternator whine and is eliminated by installing a radio choke or a filter capacitor in the power feed wire to the radio. SEE FIGURE 61–23.
CAPACITOR USAGE
Ignition noise is usually a raspy sound that varies with the speed of the engine. This noise is usually eliminated by the installation of a capacitor on the positive side of the ignition coil. The capacitor should be connected to the power feed wire to either the radio or the amplifier, or both. The capacitor has to be grounded. A capacitor allows AC interference to pass through to
ADDED CHOKE
FUSE
ADDED CAPACITOR
IGNITION
VOL
SEEK SCAN
FIGURE 61–25 A “sniffer” can be made from an old antenna lead-in cable by removing about 3 in. of the outer shielding from the end. Plug the lead-in cable into the antenna input of the radio and tune the radio to a weak station. Move the end of the antenna wire around the vehicle dash area. The sniffer is used to locate components that may not be properly shielded or grounded and can cause radio interference through the case (housing) of the radio itself.
RADIO/ CD
PWR
1
PREV
2
NEXT
3
REV
4
5
FWD
6
RDM
AUDIO PUSH P-TYPE
N
TURN
E
TU
DISPL
AM FM
CD AUX
INFO
SEEK TYPE
TRAF
AUTO TUNE
AUTO VOL
FIGURE 61–23 A radio choke and/or a capacitor can be installed in the power feed lead to any radio, amplifier, or equalizer.
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FREQUENTLY ASKED QUESTION
What Does ESN Mean?
POWER OUT
ESN means electronic serial number. This is necessary information to know when reviewing satellite radio subscriptions. Each radio has its own unique ESN, often found on a label at the back or bottom of the unit. It is also often shown on scan tools or test equipment designed to help diagnose faults in the units. POWER IN CASE GROUNDED
TECH TIP
FIGURE 61–24 Many automobile manufacturers install a coaxial capacitor, like this one, in the power feed wire to the blower motor to eliminate interference caused by the blower motor.
The Separate Battery Trick Whenever diagnosing sound system interference, try running separate 14 gauge wire(s) from the sound system power lead and ground to a separate battery outside of the vehicle. If the noise is still heard, the interference is not due to an alternator diode or other source in the wiring of the vehicle.
ground while blocking the flow of DC current. Use a 470 μF, 50 volt electrolytic capacitor, which is readily available from most radio supply stores. A special coaxial capacitor can also be used in the powerline. SEE FIGURE 61–24.
RADIO CHOKE
A radio choke, which is a coil of wire, can also be used to reduce or eliminate radio interference. Again, the radio choke is installed in the power feed wire to the radio equipment. Radio interference being picked up by the antenna can best be eliminated by stopping the source of the interference and making certain that all units containing a coil, such as electric motors, have a capacitor or diode attached to the power-side wire.
BRAIDED GROUND WIRE
Using a braided ground wire is usually specified when electrical noise is a concern. The radiofrequency signals travel on the surface of a conductor rather than through the core of the wire. A braided ground strap is used because the overlapped wires short out any radio-frequency signals traveling on the surface.
AUDIO NOISE SUMMARY
In summary:
Radio noise can be broadcast or caused by noise (voltage variations) in the power circuit to the radio.
Most radio interference complaints come when someone installs an amplifier, power booster, equalizer, or other radio accessory.
A major cause of this interference is the variation in voltage through the ground circuit wires. To prevent or reduce this interference, make sure all ground connections are clean and tight. Placing a capacitor in the ground circuit also may be beneficial.
CAUTION: Amplifiers sold to boost the range or power of an antenna often increase the level of interference and radio noise to a level that disturbs the driver. Capacitor and/or radio chokes are the most commonly used components. Two or more capacitors can be connected in parallel to increase the capacity of the original capacitor. A “sniffer” can be used to locate the source of the radio noise. A sniffer is a length of antenna wire with a few inches of insulation removed from the antenna end. The sniffer is attached to the antenna input terminal of the radio, and the radio is turned on and set to a weak station. The other end of the sniffer is then moved around areas of the dash to locate where the source of the interference originates. The radio noise will greatly increase if the end of the sniffer comes close to where electromagnetic leakage is occurring. SEE FIGURE 61–25. SEE CHART 61–2. AUDIO SYSTEM OPERATION AND DIAGNOSIS
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AUDIO NOISE CONTROL SYMPTOM CHART NOISE SOURCE
WHAT IT SOUNDS LIKE
WHAT TO TRY
Alternator
A whine whose pitch changes with engine speed
Install a capacitor to a ground at the alternator output
Ignition
Ticking that changes with engine speed
Use a sniffer to further localize the source of the problem
Turn signals
Popping in time with the turn signals
Install a capacitor across the turn signal flasher
Brake lights
Popping whenever the brake pedal is depressed
Install a capacitor across the brake light switch contacts
Blower motor
Ticking in time with the blower motor
Install a capacitor to ground at the motor hot lead
Dash lamp dimmer
A buzzy whine whose pitch changes with the dimmer setting
Install a capacitor to ground at the dimmer hot lead
Horn switch
Popping when the horn is sounded
Install a capacitor between the hot lead and horn lead at the horn relay
Horn
Buzzing synchronized with the horn
Install a capacitor to ground at each horn hot lead
Amplifier power supply
A buzz, not affected by engine speed
Ground the amplifier chassis using a braided ground strap
CHART 61–2 Radio noise can have various causes, and knowing where or when the noise occurs helps pin down the location.
REAL WORLD FIX Lightning Damage A radio failed to work in a vehicle that was outside during a thunderstorm. The technician checked the fuses and verified that power was reaching the radio. Then the technician noticed the antenna. It had been struck by lightning. Obviously, the high voltage from the lightning strike traveled to the radio receiver and damaged the circuits. Both the radio and the antenna were replaced to correct the problem. SEE FIGURE 61–26.
FIGURE 61–26 The tip of this antenna was struck by lightning.
REAL WORLD FIX The General Motors Security Radio Problem A customer replaced the battery in a General Motors vehicle and now the radio display shows “LOC.” This means that the radio is locked and there is a customer code stored in the radio. Other displays and their meaning include: “InOP”
This display indicates that too many incorrect codes have been entered and the radio must be kept powered for one hour and the ignition turned on before any more attempts can be made.
“SEC”
This display means there is a customer’s code stored and the radio is unlocked, secured, and operable.
“---”
This means there is no customer code stored and the radio is unlocked.
“REP”
This means the customer’s code has been entered once and the radio now is asking that the code be repeated to verify it was entered correctly the first time.
To unlock the radio, the technician used the following steps (the code number being used is 4321). STEP 1 STEP 2 STEP 3 STEP 4
Press the “HR” (hour) button: “000” is displayed. Set the first two digits using the hour button: “4300” is displayed. Set the last two digits of the code using the “MIN” (minutes) button: “4321” is displayed. Press the AM-FM button to enter the code. The radio is unlocked and the clock displays “1:00.”
Thankfully, the owner had the security code. If the owner had lost the code, the technician would have to secure a scrambled factory backup code from the radio and then call a toll-free number to obtain another code for the customer. The code will only be given to authorized dealers or repair facilities.
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REVIEW QUESTIONS 1. Why do AM signals travel farther than FM signals?
3. How do you match the impedance of speakers?
2. What are the purpose and function of the ground plane?
4. What two items may need to be added to the wiring of a vehicle to control or reduce radio noise?
CHAPTER QUIZ 1. Technician A says that a radio can receive AM signals, but not FM signals, if the antenna is defective. Technician B says that a good antenna should give a reading of about 500 ohms when tested with an ohmmeter between the center antenna wire and ground. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 2. An antenna lead-in wire should have how many ohms of resistance between the center terminal and the grounded outer covering? a. Less than 5 ohms b. 5 to 50 ohms c. 300 to 500 ohms d. Infinity (OL) 3. Technician A says that a braided ground wire is best to use for audio equipment to help reduce interference. Technician B says to use insulated 14 gauge or larger ground wire to reduce interference. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 4. What maintenance should be performed to a power antenna to help keep it working correctly? a. Remove it from the vehicle and lubricate the gears and cable. b. Clean the mast with a soft cloth and lubricate with a light oil. c. Disassemble the mast and pack the mast with silicone grease (or equal). d. Loosen and then retighten the retaining nut.
6. If two 4 ohm speakers are connected in series, meaning the positive (⫹) of one speaker connected to the negative (⫺) of the other speaker, the total impedance will be ______________. a. 8 ohms b. 4 ohms c. 5 ohms d. 1 ohm 7. An aftermarket satellite radio has poor reception. Technician A says that a lack of a proper ground plane on the antenna could be the cause. Technician B says that mountains or tall buildings can interfere with reception. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 8. 100,000 μF means ________. a. 0.10 farad b. 0.01 farad c. 0.001 farad d. 0.0001 farad 9. A radio choke is actually a ________. a. Resistor b. Capacitor c. Coil (inductor) d. Transistor 10. What device passes AC interference to ground and blocks DC voltage, and is used to control radio interference? a. Resistor b. Capacitor c. Coil (inductor) d. Transistor
5. If two 4 ohm speakers are connected in parallel, meaning positive (⫹) to positive (⫹) and negative (⫺) to negative (⫺), the total impedance will be ________. a. 8 ohms b. 4 ohms c. 2 ohms d. 1 ohm
AUDIO SYSTEM OPERATION AND DIAGNOSIS
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Heating and Air Conditioning
62 Heating and Air-Conditioning Components and Operation
64 Heating and Air-Conditioning System Diagnosis 65 Heating and Air-Conditioning System Service
63 Automatic Air-Conditioning System Operation
chapter
62
HEATING AND AIRCONDITIONING COMPONENTS AND OPERATION
OBJECTIVES: After studying Chapter 62, the reader will be able to: • Prepare for ASE Heating and Air-conditioning (A7) certification test content area “A” (Air Conditioning System Diagnosis and Repair) and content area “C” (Heating and Engine Cooling Systems Diagnosis and Repair). • Describe how the heater functions. • Describe how the refrigeration cycle functions. • List the parts of a typical air-conditioning system. • Explain how the air-conditioning system removes heat from the passenger compartment. KEY TERMS: Absolute humidity 714 • Axial compressor 728 • Barrier hose 723 • Blower motor 714 • Boiling point 713 • Calorie (c) 713 • Capillary tube 723 • CFC-12 (R-12) 718 • Compressor 715 • Condenser 715 • Condensate line 721 • Condensation point 713 • Cycling clutch orifice tube (CCOT) 716 • Desiccant 721 • Electromagnetic clutch 717 • Ester oil 720 • Evaporator 715 • Evaporator pressure regulator (EPR) valve 718 • Freon 718 • Heat 713 • Heater core 714 • Heater hoses 714 • Heating, ventilation, and air-conditioning system (HVAC) 712 • HFC-134a (R-134a) 718 • Humidity 714 • H-valve 725 • Hygrometer 714 • Kinetic energy 713 • Latent heat of vaporization 713 • Liquid 713 • Miscible 720 • Pilot operated absolute (POA) valve 718 • Pintle valve 723 • Positive-displacement compressor 726 • Psychrometer 714 • Reed valve 727 • Relative humidity 714 • Section 609 (clean air act) 719 • Solid 713 • Superheat 724 • Swash plate 728 • Thermostatic expansion valve (TEV or TXV) system 716 • Thermo switch (icing switch or defrost switch) 718 • Vapor 713
PURPOSE AND FUNCTION Driver and passenger comfort is the primary purpose of the heating, ventilation, and air-conditioning system, often abbreviated HVAC. The heater is also needed in cold climates to prevent freezing or death.
PRINCIPLES INVOLVED On earth, matter is found in one of three different phases or states: solid, liquid, or vapor (gas). The state depends upon the nature of the substance, the temperature, and the pressure or force exerted on it. Water occurs naturally in all three states: solid ice, liquid water, and water vapor, depending upon the temperature and pressure of the location. SEE FIGURE 62–1.
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SOLID
LIQUID
VAPOR
FIGURE 62–1 Water is a substance that can be found naturally in solid, liquid, and vapor states.
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FREQUENTLY ASKED QUESTION 212°F
212°F
Why Is Liquid Sprayed from a Can Cold? If you spray a can of liquid continuously, the can becomes cold, and the liquid being sprayed becomes cold. The can becomes cold because the pressure in the can is reduced while spraying, allowing the liquid propellant inside the can to boil and absorb heat. The liquid being sprayed has also been cooled by the liquid propellant. The propellant vapor is further cooled as it decompresses when it hits the open air. Rapid decompression results in a rapid temperature drop.
CHANGES OF STATE
A solid is a substance that cannot be compressed and has strong resistance to flow. The molecules of a solid attract each other strongly, and resist changes in volume and shape. A substance is solid at any temperature below its melting point. A melting point is a characteristic of a substance, and is related to the temperature at which a solid turns to a liquid. For water, the melting point is 32°F (0°C), which means that we can observe changes between liquid water and ice under normal weather conditions. A liquid is a substance that cannot be compressed. A substance in a liquid state has a fixed volume, but no definite shape. The boiling point is the temperature at which a liquid substance turns to a vapor. For water at normal sea level conditions, the boiling point is 212°F (100°C). A vapor is a substance that can be easily compressed, has no resistance to flow, and no fixed volume. Since a vapor flows, it is considered a fluid just like liquids are. A substance changes to a vapor if the temperature rises above its boiling point. A vapor condenses to liquid if the temperature falls below it. Just like melting and freezing, the boiling point and condensation point are the same temperature. Again, the difference is simply whether heat is being added or taken away. Boiling point and condensation point temperatures are not fixed; they vary with pressure.
HEAT AND TEMPERATURE Molecules in a substance tend to vibrate rapidly in all directions, and this disorganized energy is called heat. The intensity of vibration depends on how much kinetic energy, or energy of motion, the atom or molecule contains. We measure the level of this energy as temperature. Heat and temperature are not the same. Temperature is measured in degrees. Heat is measured in calories (c). The calorie is a metric unit that expresses the amount of heat needed to raise the temperature of one gram of water one degree Celsius. Heat is also measured in British Thermal Units (BTU). One BTU is the heat required to raise the temperature of one pound of water 1°F at sea level. One BTU equals 252 calories. LATENT HEAT
Latent heat is the “extra” heat that is needed to transform a substance from one state to another. Imagine that a solid or a liquid is being heated on a stove. When the solid reaches its melting point, or the liquid reaches its boiling point, their temperatures stop rising. The solid begins to melt, and the liquid begins to boil. This occurs without any change in temperature, even though heat is still being poured in from the burner.
1 GRAM WATER + 540 CALORIES = 1 GRAM VAPOR 1 POUND WATER + 970 BTUs = 1 POUND VAPOR
FIGURE 62–2 The extra heat required to change a standard amount of water at its boiling point to a vapor is called latent heat of vaporization.
HEAT 212°F
212°F
HEAT
212°F
1 GRAM VAPOR + 540 CALORIES = 1 GRAM WATER 1 POUND VAPOR + 970 BTUs = 1 POUND WATER
FIGURE 62–3 The latent heat of vaporization that water vapor stores is given off when the vapor condenses to a liquid. The temperature stays the same. The water in the container on the stove boils at a temperature of 212°F (100°C) at sea level, for as long as any liquid water remains. As you continue to add heat with the burner, it will all be absorbed in changing the state of the liquid to a vapor. This extra, hidden amount of energy necessary to change the state of a substance is called latent heat. SEE FIGURES 62–2 AND 62–3. Latent heat is important in air-conditioning system operation because the cooling effect is derived from changing the state of liquid refrigerant to a vapor. The refrigerant absorbs latent heat of vaporization, cooling the air blown into the passenger compartment. Heat is taken away to cool the air.
TEMPERATURE, VOLUME, AND PRESSURE OF A VAPOR Unlike a solid, a vapor has no fixed volume. Increasing the temperature of a vapor, while keeping the volume confined in the same space, increases the pressure. This happens as the vibrating vapor molecules collide more and more energetically with the walls of the container. Conversely, decreasing the temperature decreases the pressure. This relationship between temperature and pressure in vapor is why a can of nonflammable refrigerant can explode when heated by a flame—the pressure buildup inside the can will eventually exceed the can’s ability to contain the pressure. Increasing the pressure by compressing a vapor increases the temperature. Decreasing the pressure by permitting the vapor to expand decreases the temperature.
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DRY THERMOMETER
COOL MOIST AIR MOISTURE BEING REMOVED FROM AIR COOL DRY AIR HEAT BEING ADDED TO AIR WARM DRY AIR
OUTSIDE AIR EVAPORATOR
BYPASS AIR DOOR WATER FILL PLUG
OUTSIDE RECIRC. AIR DOOR
TO A/C REGISTERS WET THERMOMETER PANELDEFROST DOOR
HEATER MOTOR
FIGURE 62–4 A sling psychrometer is used to measure relative humidity.
TO DEFROSTERS
INSIDE AIR TO FLOOR
PRESSURE-TEMPERATURE RELATIONSHIPS There are two aspects of the relationship between pressure and temperature that are important to understanding the operating of an HVAC system:
The temperature at which a liquid boils (and vapor condenses) rises and falls with the pressure.
Pressure in a sealed system that contains both liquid and vapor rises and falls with the temperature.
HUMIDITY
Water vapor is in the air in varying concentrations. Humidity refers to water vapor present in the air. The level of humidity depends upon the amount of water vapor present and the temperature of the air. The amount of water vapor in the air tends to be higher near lakes or the ocean, because more water is available to evaporate from their surfaces. In desert areas with little open water, the amount of water vapor in the air tends to be low. Absolute humidity is the measurement of the weight of the water vapor in a given volume of air. Relative humidity is the percentage of how much moisture is present in the air compared to how much moisture the air is capable of holding at that temperature. Relative humidity is commonly measured with a hygrometer or a psychrometer. A hygrometer depends on a sensitive element that expands and contracts, based on the humidity. Hygrometers typically resemble a clock, with the scale reading from 0% to 100% relative humidity. Permanent-recording hygrometers may be constructed so that an ink pen or electric stylus makes a continuous record on a rotating paper disc or paper-covered drum. A psychrometer uses two thermometers, one of which has the bulb covered in a cotton wick soaked in distilled water from a builtin reservoir. SEE FIGURE 62–4. The wick keeps the bulb of the “wet thermometer” wet so that it can be cooled by evaporation. To take a relative humidity reading, the psychrometer is placed in the airflow for a certain time. As the evaporator blows air, the wet bulb’s temperature drops, and the dry bulb reads the temperature of the airflow. Sling psychrometers are spun around in the air a certain number of times. Water evaporates from the cotton wick at a rate
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TEMPERATURE BLEND DOOR BLOWER HIGH-LOW AIR DOOR
FIGURE 62–5 Typical flow of air through an automotive heat, ventilation, and air-conditioning system when placed in the heat position.
inversely proportional to the relative humidity of the air; faster if the humidity is low, and slower if the humidity is high. The “dry thermometer” registers ordinary air temperature. The higher the relative humidity, the closer the readings of the two thermometers, and the lower the humidity, the greater the difference. The different temperatures indicated by the wet and dry thermometers are compared to a chart, which gives the relative humidity.
HEATING SYSTEM PURPOSE AND FUNCTION All automotive and light-truck heater systems use the hot coolant from the engine to produce heat. The heater system is designed to provide passenger comfort and the heat needed to defrost windshield and front side windows in many vehicles. Therefore the heating system is a major safety system in the vehicle. PARTS AND OPERATION The engine coolant (antifreeze and water) flows through heater hoses and a heater core. The engine water pump supplies the force necessary to circulate the engine coolant through the heater core. The heater core is a small radiator with tubes and fins that help transfer the heat from the coolant to the air flowing through the heater core. SEE FIGURE 62–5. A blower motor with a squirrel cage-type fan is usually used to force air through the heater core and into the passenger compartment. SEE FIGURE 62–6. Before the heater can function correctly, the cooling system has to be functioning correctly. The following parts are also used to control the flow of coolant and therefore control the temperature of the passenger compartment. 1. Heater control valve.
HEATER HOSE CONNECTIONS
HEATER CORE
FIGURE 62–6 A typical heater core as installed in an HVAC housing.
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EVAPORATOR CORE
FIGURE 62–7 The evaporator removes heat from the air that enters a vehicle by transferring it to the vaporizing refrigerant. FREQUENTLY ASKED QUESTION
What Is an Auxiliary Electric Water Pump? Some vehicles are equipped with an auxiliary electric water pump. The purpose and function of this pump is to help warm the interior of the vehicle by circulating coolant from the engine through the heater core when the engine is at idle speed. At idle speed, the water pump does not circulate a sufficient quantity of coolant through the heater core to warm the interior in freezing weather.
AIR-CONDITIONING REFRIGERATION CYCLE All automotive air-conditioning systems are closed and sealed. A refrigerant is circulated through the system by a compressor that is powered by the engine through an accessory drive belt. Older systems used a refrigerant, CFC-12, commonly referred to by its Dupont trade name of Freon or R-12. Starting in the early 1990s, vehicle manufacturers now all use HFC-134a, a refrigerant that is less harmful to the atmosphere. The basic principle of the refrigeration cycle is that as a liquid changes into a gas, heat is absorbed. The heat that is absorbed by an automotive air-conditioning system is the heat from inside the vehicle. This is how the system works: 1. The liquid refrigerant evaporates in a small radiator-type unit called the evaporator. As the refrigerant evaporates, it absorbs heat as it changes from a liquid to a gas. As the heat is absorbed by the refrigerant, the evaporator becomes cold. SEE FIGURE 62–7. 2. After the refrigerant has evaporated into a low-pressure gas in the evaporator, the refrigerant flows into the engine-driven compressor. The compressor compresses the low-pressure refrigerant gas into a high-pressure gas and forces the refrigerant through the system. SEE FIGURE 62–8.
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FREQUENTLY ASKED QUESTION
How Does the Inside of the Vehicle Get Cooled? The underlying principle involved in air-conditioning or refrigeration is that “cold attracts heat.” Therefore, a cool evaporator attracts the hot air inside the vehicle. Heat always travels toward cold and when the hot air passes through the cold evaporator, the heat is absorbed by the cold evaporator, which lowers the temperature of the air. The cooled air is then forced into the passenger compartment by the blower through the air-conditioning vents.
3. This high-pressure gas flows into the condenser located in front of the cooling system radiator. The condenser looks like another radiator, and its purpose and function is the same as the cooling system radiator, to remove heat from the highpressure gas. In the condenser, the high-pressure gas changes (condenses) to form a high-pressure liquid as the heat from the refrigerant is released to the air. SEE FIGURE 62–9. 4. The high-pressure liquid then flows through a device that meters the flow into the evaporator. When the high pressure of the liquid drops, it causes the refrigerant to vaporize. 5. Air is blown through the evaporator by the blower motor. The air is cooled as heat is removed from the air and transferred to the refrigerant in the evaporator. This cooled air is then directed inside the passenger compartment through vents.
EXPANSION VALVE SYSTEMS An expansion valve is attached to the inlet to the evaporator and controls the amount of refrigerant flow into the evaporator. The expansion valve controls the flow of the refrigerant based on the
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SERVICE PORT
DISCHARGE REED VALVE
PISTON
DISCHARGE PORT
CYLINDER HEAD
SWASH PLATE
CLUTCH PLATE AND HUB
CAM ROTOR
CLUTCH COIL
SHAFT SEAL
FIGURE 62–8 The compressor provides the mechanical force needed to pressurize the refrigerant.
INLET
ORIFICE TUBE SYSTEMS
TUBING
FINS OUTLET CONDENSER
FIGURE 62–9 The condenser changes the refrigerant vapor into a liquid by transferring heat from the refrigerant to the air stream that flows between the condenser fins.
temperature at the outlet of the evaporator, which is measured by a temperature-sensing bulb and tube. When the outlet of the evaporator is warm, the opening of the expansion valve is increased. This opening allows refrigerant to flow into the evaporator. As the temperature at the outlet of the evaporator decreases, the sensing bulb and tube cause the expansion valve to restrict the flow of refrigerant into the evaporator. This type of system is called the thermostatic expansion valve system—usually abbreviated TEV or TXV. SEE FIGURE 62–10.
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Many air-conditioning systems today use a fixed-orifice tube at the inlet to the evaporator. As refrigerant flows through this orifice (small hole), it expands inside the evaporator, where it absorbs heat and expands into a low-pressure gas. A pressure switch located in the low-pressure line at the outlet of the evaporator senses when the pressure is too low. Too low a pressure in the evaporator can cause the temperature of the evaporator to drop to below freezing. A cold evaporator can therefore cause the moisture in the air to freeze into ice, creating a blockage to air flow through the evaporator. Therefore, whenever the pressure drops below a certain pressure (typically about 3 to 33 PSI [214 to 228 kPa]), a pressure switch breaks the circuit to the air-conditioning compressor clutch, which stops the flow of refrigerant through the evaporator. Then, when the temperature (and pressure) increases in the evaporator, the pressure switch closes, restoring the electrical current flow to the compressor clutch and causing the compressor to start forcing refrigerant through the evaporator again. This type of system is commonly called a cycling clutch orifice tube (or CCOT) system. SEE FIGURES 62–11 AND 62–12.
THERMOSTATIC CONTROL The lower the pressure of the refrigerant, the lower the temperature. If the pressure in the evaporator is above 30 PSI (220 kPa) for R-12 or 28 PSI (193 kPa) for an R-134a system, the temperature of the evaporator will remain about freezing, 32°F (0°C). Temperature control must be used to prevent the temperature of the evaporator from
HIGH TEMPERATURE AND HIGH PRESSURE LOW TEMPERATURE AND LOW PRESSURE
LOW PRESSURE GAS
HIGH PRESSURE GAS
SUCTION LINE
DISCHARGE LINE
COMPRESSOR CONDENSER
EVAPORATOR TEMPERATURE SENSOR
OIL
LOW PRESSURE LIQUID
LIQUID LINE
THERMOSTATIC EXPANSION VALVE (TXV)
RECEIVER-DRIER
HIGH PRESSURE LIQUID
FIGURE 62–10 A typical air-conditioning system that uses an expansion valve. A temperature sensor bulb is attached to the outlet of the evaporator to control the amount of refrigerant allowed to flow into the evaporator.
HIGH TEMPERATURE AND HIGH PRESSURE LOW TEMPERATURE AND LOW PRESSURE
HIGH PRESSURE GAS
LOW PRESSURE GAS
DISCHARGE LINE
SUCTION LINE
COMPRESSOR ACCUMULATOR
CONDENSER
EVAPORATOR OIL
LOW PRESSURE LIQUID
LIQUID LINE
ORIFICE TUBE
HIGH PRESSURE LIQUID
FIGURE 62–11 A typical automotive air-conditioning system that uses a cycling clutch and an orifice tube. dropping below 32° F (0°C). At this temperature, the moisture in the air freezes. The resulting ice would clog the airflow through the evaporator. If air cannot flow through the evaporator, the air-conditioning system stops functioning and would be immediately noticed by the driver and any passengers. If the A/C is turned off, heat from the
surrounding air will melt the ice and the air-conditioning system will again function until it ices up again. A commonly used method to control evaporator temperature is to use a thermostat to control the compressor. Air-conditioning compressors use an electromagnetic clutch. SEE FIGURE 62–13.
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O-RING ORIFICE (EXPANSION) TUBE
TO CONDENSER
TO EVAPORATOR
FIGURE 62–12 Typical orifice tube.
FIGURE 62–14 R-134a is available in 12 oz cans as well as larger 30-lb containers.
COMPRESSOR CLUTCH COIL
COMPRESSOR DRIVE PULLEY
FIGURE 62–13 A cutaway of an air-conditioning compressor electromagnetic clutch.
Another refrigerant, HFC-134a, also called R-134a, has been selected by vehicle manufacturers to replace the ozone-harming CFC. HFC-134a compound contains two carbon atoms and four fluorine atoms plus two hydrogen atoms and is therefore called a hydrofluorocarbon. Its chemical name is tetrafluorolthene, and Dupont calls it Suva®. SEE FIGURE 62–14. The boiling points and therefore the operation characteristics of CFC-12 and HFC-134a are similar.
CFC-12 and HFC-134a Boiling Temperatures at Various Pressures When the thermostat senses that the temperature is near freezing, 32°F (0°C), the switch opens the electrical circuit to the compressor and the compressor stops circulating refrigerant. This thermostat switch is also called a thermo switch, icing switch, or defrost switch. NOTE: Older vehicles used a system to control evaporator pressure when used with a continuously-operating compressor, including: POA valve—A POA valve (meaning pilot operated absolute) EPR valve—An evaporator pressure regulator valve maintains at least 30 psi in the evaporator to prevent evaporator freeze-up.
REFRIGERANTS Air-conditioning refrigerant is used to transfer heat from the inside of the vehicle to the condenser located in the front of the vehicle. A refrigerant absorbs heat when it changes state from a liquid to a gas. One of the first refrigerants was CFC-12, commonly referred to as R-12 or by its brand name Freon, a registered trade name of the DuPont Corporation. CFC-12 consists of one carbon atom surrounded by two chlorine (CL) and two fluorine (F) atoms and is therefore called a chlorofluorocarbon (CFC) compound. Its chemical name is dichlorodifluoromethane. It is the chlorine atoms that are believed to contribute to the destroying of the ozone layer in our upper atmosphere.
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Temperature °F (°C) 0 (⫺22) 5 (⫺15) 10 (⫺12) 15 (⫺9) 20 (⫺7) 25 (⫺4) 30 (⫺1) 35 (2) 40 (4) 45 (7) 50 (10) 55 (13) 60 (16) 65 (18) 70 (21) 75 (24) 80 (27) 85 (29) 90 (32) 95 (35) 100 (38) 105 (41) 110 (43)
Pressure (PSI) (kPa) CFC-12
Pressure (PSI) (kPa) HFC-134a
9 (62) 12 (83) 15 (103) 18 (124) 21 (145) 25 (172) 29 (200) 33 (228) 37 (255) 42 (290) 47 (324) 52 (359) 47 (324) 64 (441) 70 (483) 77 (531) 84 (579) 92 (634) 100 (690) 108 (745) 117 (807) 127 (876) 136 (938)
6 (41) 9 (62) 12 (83) 15 (103) 18 (124) 22 (152) 26 (179) 31 (214) 35 (241) 40 (276) 45 (310) 51 (352) 57 (393) 64 (441) 71 (490) 79 (544) 87 (600) 95 (655) 104 (717) 114 (786) 124 (855) 147 (1013) 158 (1089)
HFC-134a is a smaller molecule than CFC-12. However, HFC-134a can more easily leak out through small holes or openings in the system. HFC-134a systems require that the inside layer of
the rubber refrigerant hoses contain a barrier to prevent penetration through the microscopic holes/standard rubber refrigerant holes. NOTE: Look at the size of a blue HFC-134a 30-pound container compared to a white CFC-12 30-pound container. The blue R-134a container is larger because it requires more HFC-134a to achieve 30 pounds. NOTE: Many vehicle manufacturers started using barriertype refrigerant hoses on their vehicles in the late 1980s in anticipation of the conversion from CFC-12 to HFC-134a in future models.
REFRIGERANTS AND THE ENVIRONMENT Air-conditioning refrigerants have been discovered to be harmful to the ozone layer. The ozone (O3) layer is in the upper atmosphere and blocks out ultraviolet rays from the sun. SEE FIGURE 62–15. It has been discovered that certain chemicals, such as chlorofluorocarbon (CFC), are rapidly destroying this layer of ozone, which is 10 to 30 miles above Earth’s surface. SEE FIGURE 62–16 for how ozone is destroyed.
MONTREAL PROTOCOL A conference was held in Montreal, Canada, in 1987, where the United States and 22 other countries agreed to limit the production of ozone-depleting refrigerants. The Clean Air Act of 1990 specified that the production of R-12 refrigerant would cease at the end of 1995. Section 609 of the Clean Air Act required the following:
All technicians who service or repair automotive airconditioning systems shall be properly trained and certified.
Recovery and recycling equipment must be properly approved.
Each shop that performs automotive air-conditioning service should comply to the Environmental Protection Agency (EPA) that it is using approved recycling equipment and that only properly trained and certified technicians are using the equipment.
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FREQUENTLY ASKED QUESTION
Is Carbon Dioxide the Next Refrigerant? Not likely. While carbon dioxide (CO2) (R744) is being used on prototype vehicles, such as the Toyota Fuel Cell Hybrid Vehicle (FCHV), it requires extremely high pressures, up to 2000 psi and is not as efficient as a refrigerant as R-134a. SEE FIGURE 62–17.
ULTRAVIOLET RAYS
DEPLETED LAYER 30 MILES/48 KM OZONE LAYER STRATOSPHERE
7 MILES/11 KM CFC'S EARTH
FIGURE 62–15 A depletion of the ozone layer allows more ultraviolet radiation from the sun to reach Earth’s surface.
FIGURE 62–17 The label on a Toyota Fuel Cell Hybrid Vehicle (FCHV) showing that CO2 is being used as the refrigerant.
HOW OZONE IS DESTROYED ULTRAVIOLET LIGHT
CHLORINE ATOM
CHLORINE MOLECULE
FREE OXYGEN ATOM
OZONE MOLECULE CHLOROFLUOROCARBON MOLECULE
OXYGEN MOLECULE
IN THE UPPER ATMOSPHERE ULTRAVIOLET THE CHLORINE ATTACKS AN OZONE MOLECULE, LIGHT BREAKS OFF A CHLORINE ATOM FROM BREAKING IT APART. AN ORDINARY OXYGEN A CHLOROFLUOROCARBON MOLECULE. MOLECULE AND A MOLECULE OF CHLORINE MONOXIDE ARE FORMED.
A FREE OXYGEN ATOM BREAKS UP THE CHLORINE MONOXIDE. THE CHLORINE IS THEN FREE TO REPEAT THE PROCESS.
FIGURE 62–16 Chlorofluorocarbon molecules break apart in the atmosphere.
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FIGURE 62–18 PAG oil used in Chrysler vehicles equipped with HFC-134a refrigerant. Notice that different oils are used for different systems depending primarily on the manufacturer of the compressor. Also notice that both PAG oils are in metal cans. PAG oil absorbs moisture so readily that it can even absorb moisture that is in the air through plastic—that is why metal containers are used.
REFRIGERANT OILS The oil carried by the refrigerant through the various components is often the only source of lubrication for the compressor. The oil used must be able to be mixed without separating in the refrigerant. This characteristic of being able to be mixed is called miscible. CFC-12 systems must use mineral oil. Mineral oil is not miscible in HFC-134a, and so such systems must use synthetic polyalkyline glycol, usually referred to as PAG oil. There are numerous different PAG oils, and each vehicle manufacturer (or air-conditioning compressor manufacturer) recommends which PAG to use. SEE FIGURE 62–18. Another type of refrigerant oil is called ester oil. Ester is a classification of hydrocarbons and is specified for use in air-conditioning systems that have been charged (retrofitted) from CFC-12 to HFC-134a. Ester oil will mix with any remaining mineral oil and will work to lubricate the system even if some CFC-12 is still in the system. SEE FIGURE 62–19. All refrigerant oils have a viscosity rating. Viscosity is the measure of the oil’s thickness or resistance to flow. Always use the type and viscosity of oil specified by the manufacturer. CAUTION: Failure to use the correct refrigerant oil in an air-conditioning system can cause serious (and expensive) damage to the air-conditioning compressor. Always use the refrigerant oil specified by the manufacturer.
CONDENSER The condenser looks like a cooling system radiator. In fact, a condenser is a radiator because it is designed to radiate heat from the refrigerant to the outside air. When the refrigerant leaves the compressor it is over 300°F (150°C) as it enters the condenser. Even on a hot 100°F (38°C) day, there is a difference in temperature between the outside air around the condenser and the temperature of the refrigerant inside the
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FIGURE 62–19 Ester refrigerant oils are often specified for use when retrofitting an R-12 system to R-134a by companies who supply refit kits. Ester refrigerant oil is not recommended by many vehicle or air-conditioning compressor manufacturers. Always use the recommended refrigerant oil for the vehicle and system being serviced.
condenser. Heat always travels hot to cold. Therefore, the heat in the hot refrigerant has a natural tendency to radiate into the outside air. As the heat travels into the air, the high-pressure gas refrigerant changes state and becomes a high-pressure liquid. This is the reason the condenser is called by that name: as the heat leaves the refrigerant, it condenses from a gas (vapor) to a liquid. SEE FIGURE 62–20. To help in the heat transfer, most vehicles are equipped with cooling fans driven either electrically or by the engine through an accessory drive belt. The fan draws air through the condenser and increases the heat transfer rate.
EVAPORATOR The evaporator looks like a small radiator that is located in the evaporator housing on the passenger side of the bulkhead (firewall). The purpose of the evaporator is to transfer heat from the air to the refrigerant flowing through it. Heat from the air causes the low-pressure liquid inside the evaporator to evaporate into a low-pressure gas. As the refrigerant changes state from a liquid to a gas, it absorbs heat. A blower motor equipped with a squirrel cage–type fan circulates air through the evaporator and forces the cooler air into the passenger compartment. Another benefit of the cooling of the air is a result of what happens to any moisture that may be in the air. Moisture in the air is called relative humidity and represents the percentage of water vapor that could be in the air to the actual amount in the air. High humidity feels uncomfortable. Because the evaporator is cold (usually just above the freezing point of 32°F (0°C)), any moisture in the air condenses on its cool surface. This removes the moisture from the air and lowers the relative humidity. The moisture that condenses
HIGH-PRESSURE VAPOR HIGH-PRESSURE LIQUID LOW-PRESSURE VAPOR LOW-PRESSURE LIQUID
CONDENSER
CONDENSER
HIGH-SIDE SERVICE FITTING (DISCHARGE)
HIGH-SIDE SERVICE FITTING (DISCHARGE)
ORIFICE TUBE
RECEIVER-DRIER
HIGH SIDE
HIGH SIDE
COMPRESSOR
COMPRESSOR LOW SIDE
LOW SIDE
EXPANSION VALVE LOW-SIDE SERVICE FITTING (SUCTION)
LOW-SIDE SERVICE FITTING (SUCTION)
EVAPORATOR
EVAPORATOR ACCUMULATOR
FIGURE 62–20 The condenser serves the same function for both the orifice-tube and the expansion valve–type air-conditioning system, and that is to remove the heat from the refrigerant and cause the hot refrigerant vapors to condense into a hot liquid.
TECH TIP Broken Condenser Line? Check the Engine Mounts! Most air-conditioning systems use aluminum and flexible rubber lines between the compressor and the condenser. Because the compressor is mounted on and driven by the engine and the condenser is mounted to the body, these lines can break if the engine mounts are defective. The rubber hoses attached between the aluminum fittings of the compressor and condenser are designed to absorb normal engine movement. Worn engine mounts would allow the engine to move too much. Aluminum lines cannot stand to be flexed without crushing and breaking. Therefore, the wise technician will carefully inspect and replace any and all worn engine mounts if a broken aluminum condenser line is discovered to prevent a premature failure of a replacement condenser. SEE FIGURE 62–21.
out of the air then becomes water that is allowed to flow out of the evaporator housing and onto the ground. SEE FIGURE 62–22. NOTE: If the carpet (or floor) of the vehicle is wet on the passenger side, the cause is often a clogged evaporator drain hose. The opening, called the condensate line, is frequently clogged with mud, road debris, or leaves. To check the drain opening, hoist the vehicle and insert a wire or screwdriver into the end of the hose opening at the bottom of the evaporator housing.
LINE FROM THE COMPRESSOR TO THE CONDENSER
REPAIRED CONDENSER LIQUID LINE
FIGURE 62–21 A repaired condenser refrigerant line.
RECEIVER-DRIER A receiver-drier is used on an air-conditioning system that uses an expansion valve. The receiver-drier is located between the condenser and the evaporator. This section of the air-conditioning system contains high-pressure liquid refrigerant. The purpose of the receiver is to provide temporary storage for the liquid refrigerant and it also usually includes a filter to trap debris and a desiccant to remove moisture. Many receiver-driers contain a sight glass that provides a view of the liquid refrigerant in the system. A drier is needed to remove moisture from the system. The drier contains a desiccant (usually silica alumina or silica gel). A
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HIGH-PRESSURE VAPOR HIGH-PRESSURE LIQUID LOW-PRESSURE VAPOR EXPANSION VALVE
LOW-PRESSURE LIQUID
EVAPORATOR
CONDENSER
COMPRESSOR
RECEIVER-DRIER ACCUMULATOR
EVAPORATOR CONDENSER
FIXEDORIFICE TUBE COMPRESSOR
FIGURE 62–22 The evaporator serves the same function for both the orifice-tube and the expansion valve–type air-conditioning system, and that is to allow the liquid refrigerant to evaporate and absorb heat from the passenger compartment.
desiccant is a drying agent that absorbs any moisture (water) that gets into the air-conditioning refrigerant system. Moisture can combine with refrigerant to form an acid. Water can also freeze and form ice in the system. The desiccant is classified as XH-5 for CFC-12 systems and XH-7 or XH-9 for HFC-134a systems. The desiccant used on a CFC-12 system is not compatible with HFC-134a systems. Therefore, whenever a system is changed (retrofitted) from CFC-12 to HFC-134a, the desiccant must be replaced. The desiccant (accumulator or receiver-drier) should also be replaced on any air-conditioning system that has been left open to the atmosphere for any length of time (over 24 hours) or whenever the system has been left in a discharged condition. SEE FIGURE 62–23.
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ACCUMULATOR An accumulator is used on systems that use an orifice tube. It is located between the evaporator and the compressor. The refrigerant in this section of the refrigerant cycle is a low-pressure gas. The purposes of the accumulator include:
Preventing liquid refrigerant from reaching the compressor NOTE: A liquid cannot be compressed. If liquid refrigerant were to enter the compressor, the compressor would lock up and be damaged.
IN INLET FROM EVAPORATOR
OUTLET TO COMPRESSOR
SIGHT GLASS
INLET OUTLET
VAPOR RETURN TUBE
HOLE
FILTER PADS DESICCANT
DESICCANT BAG
PICKUP TUBE
OIL RETURN ORIFICE FILTER
FIGURE 62–23 Expansion-valve systems store excess refrigerant in a receiver-drier, which is located in the high-side liquid section of the system, whereas orifice-tube systems store excess refrigerant in an accumulator located in the low-side vapor section of the system.
EVAPORATOR HOUSING
ACCUMULATOR
LOW PRESSURE CYCLING SWITCH
between the compressor and the other air-conditioning components that are attached to the body of the vehicle. These flexible refrigerant hoses are constructed from many layers of rubber and fabric. SEE FIGURE 62–25. Most hoses used on vehicles since the early 1990s use a nonpermeable inside layer of material that prevents the loss of refrigerant through the hose itself. These hoses, called barrier hoses, are required for use with HFC-134a refrigerant.
THERMOSTATIC EXPANSION VALVES FIGURE 62–24 A typical accumulator used on a cycling clutch orifice-tube (CCOT) system.
Holding a reserve of refrigerant
Holding the desiccant (helping to remove moisture from the system)
SEE FIGURE 62–24.
REFRIGERANT LINES AND HOSES Aluminum tubing is used to connect many stationary items together like the condenser to the receiver-drier and the receiver-drier to the evaporator. Rubber lines are usually used to and from the compressor. Because the compressor is attached to the engine and the engine is mounted on flexible rubber mounts, there is movement
Thermostatic expansion valve (TXV) systems, as shown in FIGURE 62–26, use a temperature-sensitive bulb located on the evaporator outlet tube. The sensing bulb is insulated with a special tape, so it reacts only to temperature changes it senses from the outlet tube. The sensing bulb works in combination with a pressuresensitive diaphragm inside the TXV body to control the size of the variable orifice. This regulates the rate at which liquid refrigerant flows into the evaporator. The key to the operation of the expansion valve is the variable orifice. In these systems, the outlet from the high-pressure side to the low-pressure side is a variable-diameter hole. A pintle valve is a ball-and-seat valve used to increase or decrease the size of the opening. SEE FIGURE 62–27. The expansion valve uses the pintle valve to control how rapidly refrigerant enters the evaporator. The expansion valve controls the refrigerant flow in response to the temperature of the evaporator outlet, measured by the remotely mounted sensing bulb and capillary tube. SEE FIGURE 62–28. The sensing bulb may be clamped to the outlet pipe or mounted inside a passage near the outlet of the evaporator. The bulb and tube contain refrigerant. The rise or fall of the evaporator outlet
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RIGID LINES EXPANSION VALVE
RECEIVER-DRIER
FLEXIBLE HOSES RADIATOR COMPRESSOR
VIBRATION DAMPER
FLEXIBLE HOSE
CONDENSER
FIGURE 62–25 Rigid lines and flexible hoses are used throughout the air-conditioning system. The line to and from the compressor must be flexible because it is attached to the engine, which moves on its mounts during normal vehicle operation.
EXPANSION VALVE
TO EVAPORATOR
SEE FIGURE 62–29. As the capillary tube warms, the refrigerant
FROM CONDENSER
CAPILLARY TUBE
SENSING BULB
FIGURE 62–26 A typical expansion valve which uses an inlet and outlet attachment for the evaporator, and a temperature-sensing bulb that is attached to the evaporator outlet tube.
temperature causes the refrigerant in the bulb to expand or contract, resulting in a rise or fall of pressure inside the capillary. This outlet-temperature-sensitive pressure is applied to one side of the spring-loaded diaphragm inside the expansion valve.
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inside expands, forcing the diaphragm downward. The diaphragm magnifies this pressure and uses it to open the valve by pushing the pintle and ball away from its seat. This increases the size of the orifice and allows more refrigerant into the evaporator, increasing the cooling capacity. When the evaporator cools in response to the boiling of the added refrigerant, the refrigerant in the capillary tube contracts. This relieves the pressure on the expansion valve diaphragm, which closes the pintle and ball, and reduces refrigerant flow. Pressure on the top of the diaphragm is applied through the capillary tube. The equalizing pressure on the underside of the diaphragm can be internal (from the evaporator inlet) or external (from the evaporator outlet):
An internally equalized expansion valve has a passage that permits evaporator inlet pressure to reach the underside of the diaphragm.
An externally equalized expansion valve has an extra line mounted to the underside of the diaphragm housing. This line monitors the outlet pressure of the evaporator. The connection can be either at the outlet of the evaporator or at the outlet of the evaporator pressure control device.
In an expansion-valve system, the refrigerant vapor that leaves the evaporator is warmer than the liquid refrigerant that entered it. The heat that warms the refrigerant is referred to as superheat.
SENSING BULB PINTLE VALVE BALL SEAT SLOT
DIAPHRAGM
LIQUID REFRIGERANT INLET
PUSH PINS BALL AND PLATE ASSEMBLY EXPANSION VALVE SPRING
TO EVAPORATOR
FIGURE 62–27 A slot cut in the ball seat inside the expansion valve permits a small amount of refrigerant and oil to pass through at all times, even when the valve is closed. This flow of oil through the system is necessary to make sure that the compressor receives the oil it needs for lubrication.
The cycling-clutch switch, which senses the suction line, detects the evaporator outlet temperature and cycles the compressor clutch to control system cooling. This capillary device does not directly control the metering orifice. SEE FIGURE 62–32.
SENSING BULB CAPILLARY TUBE
EXPANSION VALVE
FIGURE 62–28 The sensing bulb is attached to the evaporator outlet tube. Refrigerant inside the bulb expands or contracts in response to the evaporator temperature.
Superheat is usually measured as the actual temperature difference between the boiling point of the refrigerant at the inlet and at the outlet of the evaporator. Typical values for superheat in an evaporator are between 4° and 16°F (3° and 10°C). Superheat is important because it ensures that all (or almost all) of the refrigerant vaporizes before leaving the evaporator. Chrysler uses a valve called an H-valve. It includes both the temperature-sensing and pressure-sensing functions of the expansion valve, but does not have any external tubes. The H-valve has two refrigerant passages that form the legs of the “H” as shown in FIGURES 62–30 AND 62–31. The lower passage is the refrigerant line from the condenser to the evaporator, and contains the ball and spring valve. The upper passage is the refrigerant line from the evaporator to the compressor, and contains the temperature-sensing element. A pushrod connects the diaphragm of the temperature sensor located at the top of the block to the valve ball at the bottom.
FIXED-ORIFICE TUBES Liquid refrigerant flows from the condenser to the orifice tube. As with expansion valves, fixed-orifice tubes provide a restriction that separates the high-pressure from the low-pressure side of the system. SEE FIGURE 62–33. When it reaches the fixed-orifice tube, the refrigerant undergoes rapid expansion and changes from a warm, high-pressure liquid to a cold, low-pressure liquid and vapor mixture. As it passes through the restriction to the low side, the refrigerant changes state from a liquid to a vapor because the pressure in the evaporator is so much lower than in the refrigerant line upstream from the orifice tube. The refrigerant begins to vaporize quickly as it absorbs the heat from the evaporator. The orifice tube, located between the condenser and the evaporator inlet, may be inserted in the refrigerant line or may be part of the inlet refrigerant line assembly.
COMPRESSORS The air-conditioning compressor is driven by the engine with an accessory drive belt. A magnetic clutch is usually used to connect and disconnect the drive pulley to the compressor as needed for cooling or defrosting. The compressor performs the following functions:
Compresses the low-pressure gas refrigerant from the evaporator into a high-pressure gas that is then sent to the condenser
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CAPILLARY TUBE
SENSING BULB
DIAPHRAGM
INTERNAL EQUALIZING PASSAGE
PASSAGE CLOSED
PASSAGE OPEN
CLOSED OPEN
FIGURE 62–29 Pressure from the capillary tube pushes on the spring-loaded diaphragm to open the expansion valve. As the pressure in the capillary tube contracts, the reduced pressure on the diaphragm allows the valve to close.
PRESSURE SENSITIVE DIAPHRAGM
CYCLINGCLUTCH SWITCH
TEMPERATURE SENSITIVE ELEMENT
LOW-PRESSURE CUT-OFF SWITCH FROM EVAPORATOR
TO COMPRESSOR
SUCTION LINE
PUSHROD TO EVAPORATOR
FROM CONDENSER
BALL AND SPRING
FIGURE 62–30 An H-valve (H-block) combines the temperaturesensing and pressure-regulating functions into a single assembly.
CAPILLARY TUBE
CAPILLARY TUBE WELL
H-BLOCK VALVE
FIGURE 62–32 In this Chrysler system, a low-pressure cutoff switch and a cycling-clutch switch are mounted on the H-valve.
Raises the temperature of the gas so that there is a difference in temperature between the outside (ambient) air and the refrigerant in the condenser
Acts as the pump used to circulate the refrigerant throughout the system
Often switches on and off (cycles) to control evaporator temperatures
Is the major reason why there is refrigerant oil in the system. The oil in the refrigerant lubricates the moving parts of the compressor.
POSITIVE-DISPLACEMENT PISTON COMPRESSORS FIGURE 62–31 An H-valve as used on a Chrysler minivan.
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A positive-displacement compressor displaces a constant, uniform volume of refrigerant for each revolution or operating cycle. Most
automotive air-conditioner compressors are positive-displacement piston designs. These compressors have from one to 10 cylinders depending on manufacturer and application. Most of these compressors use a piston-in-cylinder arrangement with intake and discharge strokes to draw in, compress, and discharge refrigerant. SEE FIGURE 62–34.
LIQUID LINE
EVAPORATOR
ORIFICE TUBE
FITTING
INLET TUBE
FIGURE 62–33 The orifice tube is usually located at the inlet tube to the evaporator.
DISCHARGE VALVE CLOSED SUCTION VALVE OPEN
The compressor intake stroke is also known as the suction stroke. The suction stroke of a positive-displacement compressor is like that of a two-stroke gasoline engine. Just as the intake stroke of an engine’s piston creates a low-pressure area that draws the air–fuel mixture in through the cylinder head, the suction stroke of the compressor piston creates a low-pressure area to draw refrigerant vapor into the cylinder. However, the similarity ends here. In a two-stroke engine, the compression stroke compresses the air–fuel mixture inside a sealed cylinder, with both the intake and exhaust valves closed. In the two-stroke piston AC compressor, the discharge valve does not resist the refrigerant flow during the upward piston stroke. As the compressor operates, the maximum possible charge of refrigerant vapor has been drawn in at bottom dead center of the compressor piston’s suction stroke. When the piston begins its discharge stroke, the pressure increases, shutting the suction valve and opening the discharge valve at the same time. The charge of refrigerant vapor is pushed out of the compressor into the highside refrigerant line and travels toward the condenser. Therefore, the refrigerant vapor is compressed simultaneously throughout the entire high side of the air-conditioning system. All piston compressors use one suction valve and one discharge valve for each piston. The typical valve used in compressors is the reed valve: a one-way, flap-type check valve that is built into the valve plate which seals one or more cylinders. SEE FIGURE 62–35 on page 728. A reed valve flaps away from the valve plate to open, and toward the valve plate to close. Pressure pushes the valve in one direction or the other. The suction reed valve is located on the underside of the valve plate. When the suction created by the piston’s downward stroke becomes strong enough, the suction reed valve bends, or flaps, off its seat. Low-pressure refrigerant vapor then flows into the compressor. The refrigerant vapor fills the partial vacuum created by the moving piston.
DISCHARGE VALVE OPEN SUCTION VALVE CLOSED
PISTON
COMPRESSOR BODY
SUCTION STROKE
DISCHARGE STROKE
FIGURE 62–34 In a positive-displacement compressor, the descending piston creates a drop in pressure inside the cylinder. The resulting pressure differential allows low-side pressure to force the suction valve open. Refrigerant then flows into the cylinder. On the piston’s discharge stroke, the pressure caused by the ascending piston closes the intake valve and forces the refrigerant out the discharge valve.
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REED VALVE
VALVE PLATE ASSEMBLY
SERVICE PORT ASSEMBLY
DRIVE SHAFT SEAL ASSEMBLY
COMPRESSOR BODY
CYLINDER HEAD
GASKETS
FIGURE 62–35 A reed valve is a one-way check valve that flaps away from the valve plate to open, and toward the valve plate to close.
The discharge reed valve is on the top side of the valve plate. The partial vacuum in the cylinder also pulls the discharge valve tightly against its seat, sealing off the system’s high side from the cylinder during the suction stroke. The reeds behave in exactly the opposite way during the piston’s discharge stroke. The increasing cylinder pressure pushes the suction valve tightly against its seat, sealing off the system’s low side. The discharge valve on the opposite side of the valve plate is unseated as the pressure in the cylinder increases as a result of the upward moving piston. The piston pushes the refrigerant through the discharge valve, out of the compressor, and into the air-conditioning system high side.
PISTONS AND RINGS The basic two-stroke cycle depends upon the pistons and their sealing rings to provide an adequate seal against the high-side refrigerant pressure. Most piston compressors have from two to six cylinders. Some compressors use a swash plate, or axial plate. This plate is rigidly mounted to the belt-driven shaft at an angle. SEE FIGURE 62–36 on page 729. The pistons may be on one or both sides of the plate. The pistons are connected to the swash plate by means of a large ball bearing. As the pulley turns, the shaft and angled swash plate assembly rotate. This forces the pistons back and forth in their bores. In this way, the swash plate changes the rotating action of the shaft to a reciprocating action that provides driving force for each piston. Compressors that use a swash plate are often called axial compressors.
TECH TIP The Radio “POP” Trick Most air-conditioning compressor clutch circuits contain a diode that is used to suppress the high-voltage spike that is generated whenever the compressor clutch coil is disengaged (turned off). If this diode were to fail, a high voltage (up to 400 volts!) could damage sensitive electronic components in the vehicle including the electronic air-conditioning compressor clutch control unit (if so equipped). Another thing that can occur is that the radio will often turn off and then back on whenever the electronics inside the radio detect a high-voltage spike. This can create a “pop” in the radio that is very intermittent because it only occurs when the air-conditioning compressor clutch cycles off. To check this diode, simply tune the radio to a weak AM station near 1400 Hz and cycle the air-conditioning compressor on and off. If a “pop” is heard from the radio speaker(s), then the diode is defective and must be replaced. NOTE: While some A/C compressor diodes can be replaced separately, some of these air-conditioning compressor clutch diodes are part of an entire wiring harness assembly.
VARIABLE DISPLACEMENT COMPRESSOR
Some airconditioning systems use variable displacement to control the amount of refrigerant flowing through the evaporator. The pressure difference between the high side and the low side causes the swash plate to move inside the compressor. As the swash plate changes
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its angle, the stroke of the piston is increased for more cooling or decreased to reduce the amount of cooling. SEE FIGURE 62–37 on page 729.
DRIVESHAFT
SUCTION
DISCHARGE
PISTON
SWASH PLATE
DRIVE HUB
FIGURE 62–37 A V-5 variable displacement compressor. Internal pressures act on the swash plate, which changes the stroke of the piston and then displacement based on the pressures in the system.
COMPRESSION
SUCTION
REAL WORLD FIX What Throttle Switch? A service technician was tracing the cause of an inoperative air compressor on a Saab. The service manual showed a schematic of the air-conditioning compressor that indicated a number of switches that had to be closed for the compressor clutch to be supplied with battery voltage. Besides the low pressure switch (to assure that the system is charged so as not to damage the compressor), a throttle switch was shown on the schematic. Obviously, someone else had worked on the vehicle because the throttle switch was missing entirely—just two wires remained to indicate that anything had been installed. Connecting the two wires together provided voltage to the air-conditioning compressor clutch. The customer decided not to replace the throttle switch after learning that its purpose was to disconnect (open circuit) the air-conditioning compressor when the throttle was at wide open positive to allow the maximum power for passing.
DISCHARGE
SUCTION
FIGURE 62–36 The swash plate, attached to the crankshaft at an angle, converts the pulley’s rotary motion to axial motion, which drives the pistons in a reciprocating motion.
COMPRESSOR CONTROLS Most air-conditioning compressors use an electromagnetic clutch. A coil of wire inside the clutch creates a strong magnetic field that when activated connects the input shaft of the compressor to the drive pulley. Most electromagnetic coil assemblies have between 3 and 4 ohms of resistance. According to Ohm’s law, about 3 to 4 amperes of current are required to energize the air-conditioning compressor clutch. All electrical circuits require three things to operate:
Low-pressure switch: This pressure switch is electrically closed only if there is at least 25 psi of refrigerant pressure. This amount of pressure means that the system is sufficiently charged to provide lubrication for the compressor. This switch also prevents the air-conditioning compressor from being engaged when the temperature is low (low temperature means low refrigerant pressures). SEE FIGURE 62–38.
High-pressure switch: This pressure switch is located in the high-pressure side of the air-conditioning system. If the pressure exceeds a certain level (typically 375 psi [2,600 kPa]), the pressure switch opens, thereby preventing possible damage to the air-conditioning system due to excessively high pressure.
1. A voltage source 2. An electrical load (the air-conditioning compressor clutch) 3. A ground connection All three of these must be in sync before current (amperes) can flow causing the compressor clutch to engage. Most vehicle manufacturers connect several components in series with the compressor clutch so that all have to be functioning before the compressor clutch can be engaged. The most commonly used switches include:
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PRESSURE SWITCHES
Power steering pressure switch: This switch is used on many vehicles, especially those with four-cylinder engines. It opens the circuit to the air-conditioning compressor clutch when the driver turns the steering wheel. This reduces the load on the engine at the same time power is needed by the power steering pump. Because the wheel is seldom held in a turning maneuver for a long period of time, this stoppage of the air-conditioning compressor has little, if any, effect on passenger cooling.
FIGURE 62–38 Typical air-conditioning pressure switches. A service manual would be needed to determine the function of each switch. One switch could be the low-pressure switch and the other a high-pressure switch.
REVIEW QUESTIONS 1. Discuss how the air-conditioning system removes moisture from the air.
3. Explain why a desiccant is needed in automotive air-conditioning systems.
2. Describe the operation of the typical automotive air-conditioning system.
4. List three methods used to prevent the evaporator from becoming too cold and freezing.
CHAPTER QUIZ 1. Technician A says that heat is measured in degrees. Technician B says that temperature is measured in degrees. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 2. When the defrost setting is selected, the air-conditioning compressor operates. a. True b. False 3. Where in the air-conditioning system is the refrigerant a low-pressure gas? a. Condenser outlet c. Evaporator inlet b. Evaporator outlet d. Condenser inlet 4. Where in the air-conditioning system is the refrigerant a highpressure liquid? a. Condenser outlet c. Evaporator inlet b. Evaporator outlet d. Condenser inlet 5. The compressor operates continuously with which type of system controls? a. Orifice tube b. POA/EPR 6. Technician A says that all HFC-134a uses the same refrigerant oil. Technician B says that refrigerant oil, regardless of type, must be kept in a sealed container to keep it from absorbing moisture from the air. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
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7. A front-wheel-drive vehicle has a broken condenser line. What other vehicle component may also be defective that could have caused the condenser line to break? a. Shock absorbers b. Engine mounts c. Cooling fan d. Air-conditioning compressor drive belt 8. Clear water is observed dripping out from beneath the evaporator. Technician A says that is normal. Technician B says that the evaporator housing is defective and should be replaced. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 9. The material used to absorb moisture from inside the airconditioning system is called: a. Drier b. Desiccant c. Ester d. PAG 10. Which position on the climate control panel should the driver select to avoid having the air-conditioning compressor turn on? a. Heat b. Defrost c. A/C d. Both a and b
chapter
63
AUTOMATIC AIR-CONDITIONING SYSTEM OPERATION
OBJECTIVES: After studying Chapter 63, the reader will be able to: • Prepare for ASE Certification test content area Heating and Air Conditioning (A7), test content area “D,” Operating Systems and Related Controls Diagnosis and Repair. • Identify the type of HVAC system being used on a vehicle. • Describe how dual-climate and rear air-conditioning systems work. • Discuss vacuum and electric motor controls. KEY TERMS: Afterblow 731 • Ambient air temperature sensor 732 • Aspirator tube 732 • Automatic temperature control (ATC) system 732 • Cabin filter 732 • Discharge air temperature (DAT) sensor 732 • Dual-position actuator 732 • Hybrid electric vehicle (HEV) 736 • Photo diode 732 • Three-position actuator 732 • Variable-position actuator 732
AIRFLOW MANAGEMENT All automatic heating, ventilation, and air-conditioning (HVAC) systems use a combination of the following components to control airflow into the passenger compartment:
Vents
Ducts
Air doors (also called flap doors or valves)
AIR DISTRIBUTION SECTION
HEATER DOOR
PLENUM SECTION TEMPERATURE BLEND DOOR
AIR INLET SECTION
FRESH AIR
RECIRC/FRESH AIR DOOR
RECIRC AIR TO FLOOR DEFROST DOOR
TO DEFROST EVAPORATOR
BLOWER MOTOR
HEATER CORE
The use of these components allows the system to provide airflow under the following conditions: 1. Fresh outside air or recirculated air 2. Air conditioning 3. Defrost
TO PANEL REGISTERS
FIGURE 63–1 The three major portions of the A/C and heat system are air inlet, plenum, and air distribution. The shaded portions show the paths of the four control doors.
4. Heat
SEE FIGURE 63–1. The following are the typical settings for a manual or automatic air-conditioning system. Heat
Temperature set to the desired setting
Air intake—select outside air (for faster heating, select recirculation for the first few minutes)
Air conditioning set to off
Set airflow to flow
Fan speed to desired speed
Air Conditioning
Temperature set to the desired setting
Air intake—set to outside air (for faster cooling, select recirculation for the first few minutes)
Airflow—select dash vents (also called panel vents)
Air conditioning set to on
Fan speed set to desired speed
?
FREQUENTLY ASKED QUESTION
What Is “Afterblow”? Afterblow is a term used to describe the operation of the blower motor after the ignition has been turned off. The purpose of afterblow is to dry the evaporator to help prevent the formation of mold and mildew in the evaporator case. The operation of the blower motor after the ignition is turned off has created some customer complaints. Check service information to be sure that the condition is normal or not on the vehicle being investigated. For example, in a typical General Motors system, the following conditions must be met for afterblow to occur: 1. The engine has been off for 30 minutes. 2. The outside air temperature is 70°F (21°C) or higher. 3. The battery voltage is 12 volts or higher. If the above conditions exist, the afterblow is commanded to be on for 20 seconds, off for 10 seconds, and then back on for another 20 seconds.
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Ventilation
Temperature set to lowest temperature
Air intake—select outside air
Airflow—set to dash (panel) vents
Air conditioning set to off
Fan speed set to desired speed
FLOOR PANEL DOOR ACTUATOR (BEHIND SHIELD)
BLEND DOOR ACTUATOR
AMBIENT TEMPERATURE SENSOR
Defogging or Defrosting the Inside of the Windshield
Temperature set to high temperature
Air intake set to outside air
Airflow set to windshield
Fan speed set to desired speed
AUTOMATIC AIR CONDITIONING Automatic air-conditioning systems are usually called automatic temperature control (ATC) systems. Automatic systems use many of the same components as a normally adjusted system but with additional sensors. These sensors and their purpose and function include:
OUTSIDE AIR TEMPERATURE (OAT) SENSOR
This sensor is usually located at the front of the vehicle behind the grille but in front of the radiator. The purpose of this sensor is to detect the temperature of the outside air. This sensor is commonly called the ambient air temperature sensor and is also used to supply temperature information for the driver on a display. SEE FIGURE 63–2.
INSIDE VEHICLE TEMPERATURE SENSOR Many older ATC systems used a temperature sensor located behind the instrument panel. Air to the sensor was forced to flow past the sensor by using an aspirator tube, which was connected to the blower motor case. DISCHARGE AIR TEMPERATURE SENSOR
The discharge air temperature (DAT) sensor is located at the outlet of the vents. The purpose of this sensor is to inform the controller of the actual temperature at the discharge ducts.
BLOWER SPEED CONTROLLER
FRESH AIR DOOR ACTUATOR
FIGURE 63–2 The ambient temperature sensor in this system is located in the fresh air intake duct for the HVAC system.
ACTUATORS An actuator is a part that moves the vanes or valves. Actuators used in air-conditioning systems are either electric or vacuum operated and include three different types.
DUAL-POSITION ACTUATOR
A dual-position actuator is able to move either open or closed. An example of this type of actuator is the recirculation door, which can be either open or closed.
THREE-POSITION ACTUATOR A three-position actuator is able to provide three air door positions, such as the bi-level door, which could allow defrost only, floor only, or a mixture of the two. VARIABLE-POSITION ACTUATOR A variable-position actuator is capable of positioning a valve in any position. All variableposition actuators use a feedback potentiometer, which is used by the controller to detect the actual position of the door or valve. SEE FIGURE 63–3.
EVAPORATOR OUTLET TEMPERATURE SENSOR
This sensor is used to control the AC compressor to keep the evaporative temperature within the specified temperature range for most efficient operation.
SUNLOAD SENSOR
Sunload sensors are mounted on the top of the dash so that they can adjust the temperature and the fan speed to match the increased heating through the windows from the sun. The most common type of sunload sensor is a photo diode. This type of sensor produces a voltage which is directly related to the amount of light received. The voltage varies from 0.3 volt (dash) to 3.0 volts (light). NOTE: Some vehicles are equipped with a dual-zone sunload sensor that has two sensors included. This sensor allows the system to automatically adjust the airflow and air temperature based on the actual sun intensity experienced by both the driver and the passenger.
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CABIN FILTERS Most late-model air-conditioning systems include a cabin filter, which is an air filter in the outside air inlet. The purpose of the cabin filter is to filter dirt and dust from the air before it enters the interior of the vehicle. Cabin air filters can be accessed either in the dash, usually behind the glove box, or from under the hood. Cabin air filters should be replaced regularly, usually every two years during normal service and more often if the vehicle is driven in dusty areas. SEE FIGURE 63–4. NOTE: Some cabin filters contain activated charcoal which absorbs hydrocarbons and helps to deodorize the air as it enters the interior. For best results, use the designated replacement filter.
OUTPUTS
INPUTS
BLOWER MOTOR SPEED CONTROL A/C SUNLOAD SENSOR
A/C AIR TEMPERATURE CONTROL
AUTOMATIC TEMPERATURE CONTROL SENSOR
TEMPERATURE CONTROL DOOR
A/C BLOWER MOTOR
DOOR ACTUATOR FEEDBACK MODE AIR DOOR
A/C AMBIENT AIR TEMPERATURE SENSOR
VEHICLE OPERATOR
DOOR MOTOR
ELECTRONIC CONTROL MODULE
DEFROSTER DOOR MOTOR
AIR INLET DUCT DOOR VACUUM MOTOR A/C CYCLING SWITCH
DEFROSTER DOOR
HEATER AND A/C AIR INLET DOOR
A/C COMPRESSOR A/C CLUTCH
A/C PRESSURE CUT-OFF SWITCH
VEHICLE SPEED ENGINE COOLANT TEMPERATURE
POWERTRAIN CONTROL MODULE
OTHER ENGINE SENSORS
A/C COMPRESSOR CLUTCH CONTROL MODULE
ATC SYSTEM BLOCK DIAGRAM
FIGURE 63–3 A block diagram showing the inputs to the electronic control assembly and the outputs; note that some of the outputs have feedback to the ECM.
VACUUM CONTROL CIRCUITS Vacuum control circuits use vacuum created in the intake manifold of the engine. Because vacuum decreases to close to zero during heavy acceleration, a vacuum accumulator is used to store vacuum during the short periods of acceleration. SEE FIGURE 63–5.
ELECTRIC SERVOMOTOR CIRCUITS
FIGURE 63–4 A typical cabin filter being removed from behind the glove compartment.
Most HVAC systems use electric motors to move valves and doors. SEE FIGURE 63–6 on page 734. Each servomotor contains a feedback potentiometer, which is used by the air conditioning control unit to indicate the actual position of the valve or door. If the commanded position and the actual position are not the same, then most systems are designed to store a diagnostic trouble code indicating which door is out of calibration. SEE FIGURE 63–7 on page 734.
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BLEND DOOR MOTOR
M
NO VACUUM AC CONTROL UNIT
DOOR POSITION COMMAND CIRCUIT
COMPARATOR CALCULATION CIRCUIT
VACUUM A/D CONVERSION
FIGURE 63–5 With no vacuum signal, the spring extends the actuator shaft to place the door in a certain position (top). A vacuum signal pulls the shaft inward and moves the door to the other position (bottom).
BLEND DOOR FEEDBACK POTENTIOMETER
FIGURE 63–7 The feedback circuit signals the AC control unit with the blend door position.
FIGURE 63–6 Three electric actuators can be easily seen on this demonstration unit. However, accessing these actuators in a vehicle can be difficult.
BLOWER MOTOR CONTROL Blower motors are used to move air. The air is directed by the doors of the HVAC system. Most blower motors use resistors to control the speed of the motors by dropping the amount of current flow through the motor at the lower speed. The resistor lowers the voltage and the current to the motor. The control then allows full system voltage to be applied to the motor during high-speed operation. The blower motor resistor is always located in the plenum near the blower motor so that airflow past the resistor can help keep it cool. SEE FIGURES 63–8 AND 63–9.
FIGURE 63–8 A typical blower motor assembly with attached squirrel cage blower. A replacement motor does not include the squirrel cage blower so it needs to be switched to the replacement motor.
DUAL-ZONE CLIMATE CONTROLS Dual-zone climate controls allow the driver and the passenger to select different temperatures, as much as a 30°F (17°C) difference. In a dual-zone climate control system, the ducts and airflow are split and two air mix doors are used, with each door being controlled by its own actuator. SEE FIGURE 63–10 on page 735.
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FIGURE 63–9 A “credit card” resistor used in the rear blower assembly in a Dodge minivan.
HVAC CONTROLLER 5V
8V
DRIVER'S AIR/MIX VALVE ACTUATOR
5V
8V
8V
8V
5V
M M
PASSENGER'S AIR/MIX VALVE ACTUATOR FRESH AIR
INLET DOOR
DRIVER'S WINDSHIELD OUTLETS DRIVER'S PANEL OUTLETS
RECIRC. AIR
DRIVER'S FLOOR OUTLETS PASSENGER'S FLOOR OUTLETS BLOWER MOTOR
PASSENGER'S PANEL OUTLETS
EVAPORATOR
PASSENGER'S WINDSHIELD OUTLETS
HEATER CORE
FIGURE 63–10 A dual climate control system showing the airflow and how it splits. require a separate heater core and air-conditioner evaporator in the rear to provide adequate heating and cooling. Most rear HVAC systems include the following components:
A larger capacity air-conditioning compressor
A second evaporator located at the rear of the vehicle
A second heater core located at the rear of the vehicle
A second blower motor and blower motor control at the rear of the vehicle
Lines and fittings connecting the front heater and airconditioning components to the rear system
Rear controls for speed and temperature on some models
SEE FIGURE 63–12 AND FIGURE 63–13. FIGURE 63–11 A typical dual-zone climate control panel showing left and right side temperature control levers.
REAR AIR-CONDITIONING SYSTEM Many larger trucks, vans, and sport utility vehicles (SUVs) are equipped with rear heat and air-conditioning units. Many vehicles are equipped with ducts that route heated or cooled air to rear-seat passengers. SEE FIGURE 63–11. However, many larger vehicles
RECIRCULATION OPERATION When recirculation is selected, about 90% of the air is drawn from the passenger compartment and the other 10% is drawn from outside air. The purpose is to speed up the cooling of the inside of the vehicle. However, the body control module may also select recirculation operation if the high-side air-conditioning system pressures exceed 320 PSI (2,200 kPa) to help lower the high-side pressure using cooler inside air through the evaporator. This condition should not normally occur, but if it does, this could cause a customer concern because the blower noise is greatly increased in the recirculation position.
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FIGURE 63–12 Heated or cooled air is supplied to the rear seat passengers of most vehicles through ducts that run under the front seats.
FIGURE 63–13 A rear heat and air conditioning system on a Honda Odyssey minivan.
1. Idle-stop mode is disabled if max cooling is selected.
HYBRID ELECTRIC VEHICLE HEATING AND COOLING SYSTEMS Hybrid electric vehicle (HEV) systems need to be different than conventional systems because the engine stops when at idle if the engine is warm. As a result, the engine-driven air-conditioning compressor will also stop. To allow idle-stop mode and still provide air conditioning, several methods are used depending on the exact vehicle. These methods include:
2. Honda uses a hybrid compressor which has a smaller capacity part of the compressor being operated by an electric motor, which is powered by the high-voltage (HV) batteries. 3. Toyota uses an air-conditioning compressor that is entirely driven by the high-voltage batteries and is therefore capable of providing cooling under all conditions, including when the engine is not operating. Toyota uses electric heating devices called positive temperature coefficient (PTC) thermistor installed in the heater core to provide heat to the passenger compartment. These heaters are powered by the high-voltage electric system.
REVIEW QUESTIONS 1. What are the four airflow locations?
3. Why is a feedback potentiometer used on an electric actuator?
2. Automatic air-conditioning systems include which sensors?
4. What components are needed for rear air conditioning and heat?
CHAPTER QUIZ 1. In heating mode, where is the airflow directed? a. Dash vents b. Floor c. Windshield d. Both b and c
4. An actuator can be capable of how many position(s)? a. Two b. Three c. Variable d. All of the above
2. Which sensor is also called the ambient air temperature sensor? a. Outside air temperature (OAT) b. Inside vehicle temperature c. Discharge air temperature d. Evaporator outlet temperature
5. Some cabin filters contain ______ to absorb odors. a. Perfume b. Activated charcoal c. Paper filter material d. Synthetic fibers
3. What is the most common type of sunload sensor? a. Potentiometer b. Negative temperature coefficient (NTC) thermistor c. Photo diode d. Positive temperature coefficient (PTC) thermistor
6. Which sensor might use an aspirator tube? a. Inside vehicle temperature b. Outside air-temperature (OAT) c. Discharge air temperature d. Evaporator outlet temperature
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7. Technician A says that some cabin filters are accessible behind the glove compartment. Technician B says that some cabin filters are accessible from under the hood. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 8. The blower motor resistors are used to limit ______ to the motor. a. Voltage c. Airflow b. Current d. Both a and b
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9. Which is not part of a rear air-conditioning system? a. Rear evaporator b. Rear heater core c. Rear AC compressor d. Rear blower motor 10. What components in the air-conditioning system may be different on a hybrid electric vehicle? a. Evaporator b. Compressor c. Condenser d. Blower motor
HEATING AND AIRCONDITIONING SYSTEM DIAGNOSIS
OBJECTIVES: After studying Chapter 64, the reader will be able to: • Prepare for ASE Heating and Air Conditioning (A7) certification test content area “A” (Air Conditioning System Diagnosis and Repair), content area “B” (Refrigeration System Component Diagnosis and Repair), content area “C” (Heating and Engine Cooling Systems Diagnosis and Repair), content area “D” (Operating Systems and Related Controls Diagnosis and Repair), and content area “E” (Refrigeration, Recovery, Recycling, and Handling). • Diagnose lack of heat problems. • List the air-conditioning system performance check procedures. • Discuss methods used to locate the source of an airconditioning system leak. • Describe how to recover, evacuate, and recharge an air-conditioning system. • Discuss what is necessary to retrofit a CFC-12 system to be able to use HFC-134a refrigerant. KEY TERMS: Bleeder valves 739 • High-side pressure 741 • Low coolant level 740 • Low-side pressure 741
HVAC DIAGNOSTIC PROCEDURE
STEP 4
Check for related technical service bulletins (TSBs). If there has been a bulletin released to solve a known problem, it saves a lot of time to know what to do rather than spend a lot of time trying to find and correct a problem.
STEP 5
Determine the root cause. Be sure to find and correct the root cause of the problem. A low refrigerant level means that there was a leak in the system. Finding and correcting the leak that caused the low refrigerant level is correcting the root cause.
STEP 6
Verify the repair. Drive the vehicle under similar conditions which caused the customer to complain and verify that the concern has been corrected.
When diagnosing a heating and air-conditioning system problem, most vehicle manufacturers recommend that the following steps be performed. STEP 1
Verify the customer complaint (concern). Sometimes the customer does not understand how the system is supposed to work or does not explain the fault clearly. Verifying the fault also means that the technician can verify that the problem has been corrected after the service procedure has been performed.
STEP 2
Do a thorough visual inspection. Heating and airconditioning problems are often found by looking carefully at all of the components, checking for obvious faults or damage due to an accident or road debris.
STEP 3
Check for diagnostic trouble codes. Many heating and air-conditioning systems use sensors and actuators, which are computer controlled and will set diagnostic trouble codes in the event of component failure.
HEATER DIAGNOSIS Most of the heat absorbed from the engine by the cooling system is wasted. Some of this heat, however, is recovered by the vehicle heater. Heated coolant is passed through tubes in the small core of the heater. Air is passed across the heater fins and is then sent to the passenger compartment. In some vehicles, the heater and air
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TECH TIP Water on the Carpet? Check the Evaporator Water Drain If the evaporator water drip tube becomes clogged with mud, leaves, or debris, water will build up inside the evaporator housing and spill out onto the carpet on the passenger side. Customers often think that the windshield or door seals are leaking. Most evaporator water drains are not visible unless the vehicle is hoisted.
HEATER CORE
STEP 2
PLENUM ASSEMBLY
HEATER TROUBLE DIAGNOSIS A lack of heat from the heater or having heat coming out of the wrong vents can be a dangerous and uncomfortable problem. The first step in the diagnostic process is to perform a thorough visual inspection and perform simple tests. This includes the following:
conditioning work in series to maintain vehicle compartment temperature. SEE FIGURE 64–1.
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After the engine has been operating for 15 minutes, feel the upper radiator hose. If the engine is up to proper operating temperature, the upper radiator hose should be too hot for you to keep your hand on it. The hose should also be pressurized. a. If the hose is not hot enough, replace the thermostat. b. If the hose is not pressurized, pressure test the cooling system with a pressure tester to locate leaks. Replace the radiator pressure cap if it will not hold the specified pressure. c. If okay, see step 2.
CHAPTER 64
Carefully touch the upper radiator hose with the engine running. On most vehicles, the temperature of the hose should be so hot that you cannot keep your hand on it (between 190° to 220°F [88° to 104°C]). NOTE: An infrared thermometer (pyrometer) can be used to measure the temperature of the upper radiator hose and the area around the thermostat housing.
THERMOSTAT DIAGNOSIS
STEP 1
Check the coolant level. Low coolant level can cause a lack of heat from the heater. Low coolant level can also cause occasional loss of heat. CAUTION: Do not remove the radiator cap when the engine is hot. Allow the vehicle to sit several hours before removing the pressure cap to check the radiator coolant level.
FIGURE 64–1 The heater core is mounted inside a heater plenum chamber where air passes over it to absorb heat from the warmed engine coolant.
When the vehicle’s heater does not produce the desired amount of heat, many owners and technicians replace the thermostat before doing any other troubleshooting. While it is true that a defective thermostat can be the reason for the engine not to reach normal operating temperatures, there are many other causes that can result in lack of heat from the heater. To determine the exact cause, follow this procedure:
With the engine running, feel both heater hoses. (The heater should be set to the maximum heat position.) Both hoses should be too hot to hold. If both hoses are warm (not hot) or cool, check the heater control valve, if equipped, for proper operation. If one hose is hot and the other (return) is just warm or cool, remove both hoses from the heater core or engine and flush the heater core with water from a garden hose.
Results: If the upper radiator hose is not too hot to hold, then the engine thermostat is defective. If the radiator hose is too hot to handle, then the lack of heat from the heater is not due to a lack of hot water in the engine.
SEE FIGURE 64–2.
Results: (a) If neither heater hose is hot to the touch, it is likely there is an air pocket in the heater that is preventing the flow of coolant into the heater core. (b) If only one heater hose is hot to the touch, then the heater core is likely to be clogged or partially clogged. A clogged heater core would prevent enough hot coolant from circulating through the heater core to provide adequate heat to the passenger compartment.
VISUAL INSPECTION The diagnosis of a heater problem or concern should start with a visual inspection. The following items should be checked or tested:
TECH TIP
BLEEDER VALVE
Defrost All the Time? Check the Vacuum A common problem involves airflow from the defroster ducts even though the selector lever is in other positions. The defrost setting is the default position in the event of a failure with the vacuum supply. The defrost position is used because it is the safest position. For safety, the windshield must remain free from frost. Heat is also supplied to the passenger compartments not only through defrost ducts but also through the heater vents at floor level. If the airflow is mostly directed to the windshield, check under the hood for a broken, disconnected, or missing vacuum hose. Check the vacuum reserve container for cracks or rust (if metal) that could prevent the container from holding vacuum. Check all vacuum hose connections at the intake manifold and trace each carefully, inspecting for cracks, splits, or softened areas that may indicate a problem. HINT: This problem of incorrect airflow inside the vehicle often occurs after another service procedure has been performed, such as spark plug replacement. The movement of the technician’s body and arms can cause a hose to be pulled loose or a vacuum fitting to break without the service technician being aware that anything wrong has occurred.
FIGURE 64–2 A cable controlled heater control valve. This valve is normally open, allowing engine coolant to flow through the heater core. When the air conditioning is switched to maximum cooling, the valve shuts off the flow of coolant to the heater.
THERMOSTAT HOUSING
FIGURE 64–3 Many engines are equipped with a bleeder valve to permit a technician to bleed any trapped air from the cooling system. The valve is loosened as coolant is poured into the system. Because air is lighter than coolant, the air tends to float toward the highest part of the cooling system.
?
FREQUENTLY ASKED QUESTION
How Can You Easily Burp Air from the Cooling System? The first step in being certain there is no air in the cooling system is to try to avoid getting air into the system in the first place during cooling system service. If the engine is equipped with bleeder valves near the high spots of the cooling system, these valves should be open when refilling the radiator. SEE FIGURE 64–3. Any trapped air will always travel to the highest portion of the cooling system and escape out of these bleeder openings. Close the valves as soon as coolant is observed coming out of the valve opening. If the cooling system is not equipped with bleeder valves, fill the cooling system as full as possible and then start the engine. With the radiator cap removed, the coolant level will often rise as the trapped air is expanding, then drop down as the trapped air escapes out of the radiator neck opening. Air can still remain trapped. To help speed up the process, try installing the radiator cap just to the first notch. (In this position the radiator cap is closed, but will not seal enough to allow pressure to build in the cooling system.) To help force any trapped air from the cooling system, simply drive the vehicle normally for several miles. By driving the vehicle under load, the engine will warm up faster and the thermostat will open allowing the coolant to flow from the engine and through the radiator. Any trapped air is then released into the radiator where it can easily escape through the unsealed radiator cap. After filling the radiator, securely tighten the radiator cap and test-drive the vehicle to verify proper operation. Always check service information for the exact procedure to follow when replacing coolant.
TECH TIP The Hand Test To check a radiator or condenser for possible clogged or restricted areas, simply touch the outside of the unit with your hand. Any cool spots indicate that the radiator or condenser is clogged in that cool area.
NOTE: An air bubble could be lodged in the heater core. This is a common occurrence especially if the coolant (antifreeze) has been recently replaced. Failure to properly “burp” the air from the cooling system can cause a pocket of air to remain trapped in the heater core, preventing coolant from flowing through. See Frequently Asked Question “How Can You Easily Burp Air from the Cooling System?”
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TECH TIP CLEAR
Hot/Cold/Hot/Cold Heater Diagnosis A common customer complaint is a lack of heat from the heater but only while driving, even though there seems to be plenty of heat when the engine is at idle speed and the vehicle is stopped. This is a classic symptom of low coolant level. The lower than normal coolant level in the radiator prevents enough flow to supply the heater core. When the engine speed is reduced, the water pump turns slower and coolant can more easily flow through the heater core resulting in heat from the heater. As the engine speed increases, the water pump speed also increases. Because there is less than the proper amount of coolant in the system, the water pump will only be able to supply coolant through the engine (a path of lower resistance).
BUBBLES
OIL STREAKS
FIGURE 64–4 Many older CFC-12 systems are equipped with a sight glass either on or near the receiver-drier. A fully-charged (or completely empty) system is indicated by a clear sight glass. Bubbles or foam indicate that the system is not fully charged. An empty system may have oil streaks on the sight glass being moved by the vapor remaining in the system.
CHECKING A/C SYSTEM PERFORMANCE The first step in the diagnosis of any cooling system problem is to verify the complaint (concern). STEP 1
Start the engine and turn the A/C system to maximum with the engine operating between 1500 and 2000 RPM with the doors open. Operate the system for 5 to 10 minutes.
STEP 2
Verify by visual inspection that the A/C compressor clutch is engaged. Check the sight glass if the vehicle is so equipped, as shown in FIGURE 64–4. HINT: If the A/C compressor clutch cannot be observed, have an assistant turn the air conditioning on and then off and listen for the “click” of the A/C compressor clutch.
STEP 3
STEP 4
STEP 5
740
Place an air-conditioning thermometer in the A/C vent near the center of the vehicle. Wait several minutes to allow the system to reach maximum output and observe the thermometer. • If 35° to 45°F (2° to 7°C), the system is functioning okay. Continue a thorough visual inspection looking for any faults that may cause an intermittent problem. • If over 45°F (7°C), continue with pressure gauge testing (Step 4). Identify the refrigerant. Before connecting the pressure gauges or performing any other service to an automotive air-conditioning system, verify the refrigerant that is presently in the system. Connect a refrigerant identification machine to the system. SEE FIGURE 64–5. Connect both high-pressure and low-pressure gauges to the service ports. Start the engine and turn the air conditioning system on and set to maximum cooling. The lowside pressure should be about 25 to 35 PSI. The high-side pressure should be about 150 to 200 PSI. Compare your readings to the normal and abnormal readings in the following chart. SEE FIGURES 64–6 AND 64–7. CHAPTER 64
FIGURE 64–5 A typical refrigerant identification machine. The readout indicates what kind of refrigerant is in the system. If a blend or some other contaminated refrigerant is discovered, it should be recovered and stored in a separate container to keep it from contaminating fresh refrigerant. A/C Pressure Gauge Chart Low Side
High Side
Condition (Possible Cause)
25–35 PSI
170–200
Normal
Low
Low
Low refrigerant charge level
Low
High
Restriction in high-side line
High
High
System is overcharged. Expansion valve stuck open
High
Low
Restriction in the low-side line
TEMPERATURE AND PRESSURE MEASUREMENTS Temperature and pressure are directly related in AC systems. As the ambient temperature increases, the high-side pressure must also increase to have a heat transfer at the condenser. The temperature
(a)
(b)
FIGURE 64–6 (a) Both high-pressure (red) and low-pressure (blue) hoses have been attached to the vehicle. (b) High-side pressure can be compared to the temperature of the outlet from the compressor. Here a service technician is using an infrared pyrometer to measure the temperature.
of the vapor must be higher than the ambient temperature to allow enough heat to be removed for condensation. Also, higher ambient temperatures, and high humidity, usually mean a higher heat load on the evaporator. This means a larger quantity of heat has to be removed at the condenser. The high-side pressure is directly related to the amount of heat that needs to be removed, and the heat transfer at the condenser. Low-side pressure indicates the boiling point of the temperature of the evaporator. If the pressure is too high, the boiling point of the refrigerant and temperature of the evaporator are too high. Low-side pressure that is too low indicates the evaporator is too cold and may ice, or that there is not enough boiling refrigerant in the evaporator to remove an adequate amount of heat. SEE FIGURE 64–8. The heat transfer at the condenser is usually the cause of highside pressure that is too high. The number one cause of poor heat transfer is lack of airflow across the condenser. The vehicle is dependent upon fans to move enough air when you are testing in a stall. It may be necessary to drive the vehicle at 30 mph to get the ram air necessary to determine if lack of airflow is the reason for the poor heat transfer. Another cause of excessive high-side pressure is contamination with a different refrigerant. Mixing R-12 and R-134a raises the condensing pressure of the mixture. If the system is contaminated with R22, the pressures can become extremely high. At 150°F, the pressure of R-12 is 235 PSI (1,620 kPa), R-134a is 263 PSI (1,813 kPa), and R-22 is 381 PSI (2,627 kPa). This is an important reason to use a refrigerant identifier. As compressor efficiency is reduced, the high side decreases, and the low side increases. The function of the compressor is to pull down the low side and push up the high side. When the compressor is failing, it does not do either job well. Always look at both the high- and low-side pressures when diagnosing a problem. SEE FIGURES 64–9 THROUGH 64–11.
?
FREQUENTLY ASKED QUESTION
CONDENSER IN
What’s Wrong When the A/C Compressor Clutch Cycles On and Off Rapidly?
GAS LIQUID LINE-OVERCHARGE NORMAL LIQUID LINE
OUT LIQUID LINE-UNDERCHARGE
FIGURE 64–7 Hot refrigerant condenses in the condenser when it loses its heat to the outside air. Note how the level of the liquid line changes when undercharged or overcharged.
This is a common occurrence on a vehicle equipped with a cycling clutch orifice tube (CCOT) system that is low on refrigerant charge. With a normal charge, the low-side pressure should be 15 to 35 PSI and the clutch should be on for 45 to 90 seconds and be off for only about 15 to 30 seconds.
R134a PRESSURE-TEMPERATURE CHART AMBIENT AIR TEMPERATURE (°F)
HUMIDITY
LOW-SIDE PRESSURE (PSI)
HIGH-SIDE PRESSURE (PSI)
70
Low High Low High Low High Low High Low High
25 to 30 28 to 35 26 to 33 30 to 36 31 to 37 37 to 45 35 to 44 38 to 48 40 to 50 42 to 52
140 to 190 165 to 220 150 to 200 190 to 260 170 to 220 210 to 290 195 to 245 230 to 320 235 to 285 260 to 350
80 90 100 100
FIGURE 64–8 The average R-134a pressure–temperature readings during a performance test. The high-side pressure of R-12 systems will be lower at higher temperatures.
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FIGURE 64–12 A clogged orifice tube.
TECH TIP High-Side Pressure Tip
FIGURE 64–9 When both low- and high-side pressures are low, the system is undercharged with refrigerant.
A quick and easy way to determine the correct high-side pressure is to add 100 to the ambient air temperature in Fahrenheit. For example: 85°F outside air temperature ⫹100 185 PSI ⫽ typical normal high-side pressure
TECH TIP Clogged Orifice Tube Test A clogged orifice tube is a common air-conditioning system failure. When the orifice tube becomes clogged, it blocks the flow of refrigerant through the evaporator, which causes a reduced cooling of the passenger compartment. To check for a possible restriction in the system, follow these easy steps:
FIGURE 64–10 Both low- and high-side pressures higher than normal indicate that the system is overcharged with refrigerant.
STEP 1
Connect the A/C pressure gauge to both lowand high-side pressure fittings.
STEP 2
Operate the A/C system for 5 to 10 minutes.
STEP 3
Shut off the A/C system and watch the pressure gauges. If the pressures do not equalize quickly, then there is a restriction in the system. SEE FIGURES 64–12 AND 64–13. NOTE: To locate a restriction anywhere in the system, feel along the system lines. The restriction exists at the point of greatest temperature difference. “Frosting” is a good indication of a restriction.
TECH TIP The Fire Extinguisher Test
FIGURE 64–11 Lack of proper airflow across the condenser is usually the cause of this condition.
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To test the expansion valve, start the engine and allow the A/C system to function with the control set to “recirculate.” Using a CO2 fire extinguisher, blast the expansion valve with CO2. The valve should close and the low-side pressure should go into a vacuum. If the low-side pressure does not go into a vacuum, the expansion valve is faulty and should be replaced. SEE FIGURE 64–14.
FIGURE 64–13 Assortment of orifice tubes. Note that each is color coded and identified on the lid of the assortment. Even though some technicians have purposely installed an orifice tube with a larger opening in an attempt to increase cooling, it is always safe to use the exact orifice tube specified for the vehicle being serviced.
FIGURE 64–15 A partially clogged evaporator.
REAL WORLD FIX The Clogged Evaporator Problem The owner of an older Buick complained that the blower motor must be defective because the air no longer flowed from the air-conditioning vents as it should. A check of the blower motor circuit revealed that the blower motor was working. To confirm the operation of the blower, the resistor pack was removed and air flowed out of the opening. Then the technician discovered the cause of the lack of airflow—the evaporator was covered with oily dirt. The technician recovered the refrigerant and removed the evaporator. Apparently, the evaporator had a small refrigerant leak that allowed the refrigerant oil to coat the fins of the evaporator. Any dirt in the air stuck to the evaporator until the dirt almost completely blocked the airflow. Replacing the evaporator and recharging the system fixed the blower motor problem. SEE FIGURE 64–15.
(a)
TECH TIP The Touch, Feel Test A quick-and-easy test to check the state of charge of an orifice tube system is to use one hand and touch the evaporator side of the orifice tube. Touch your other hand to the inlet to the accumulator. The following conditions can be determined by noticing the temperature of these two locations. SEE FIGURE 64–16. Normal operation—both temperatures about the same Undercharged condition—accumulator temperature higher (warmer) than the orifice tube temperature
(b)
FIGURE 64–14 (a) A CO2 fire extinguisher equipped with the fittings necessary to test the operation of an expansion valve. (b) The size of the opening at the end of the hose determines how much CO2 is released to cool the expansion valve temperature sensor bulb.
Just remember: High pressure means that the temperature of the component or line will also be high (hot). Low pressure means that the temperature of the component or line will also be low (cold). For example, the inlet to the compressor (low pressure) should always be cool whereas the outlet of the compressor (high pressure) should always be hot.
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LOW PRESSURE CYCLING SWITCH
ACCUMULATOR
HIGH SIDE TEST PORT
LOW SIDE TEST PORT
FIGURE 64–16 If the system is fully charged, the outlet temperature of the line leaving the evaporator should be about the same as the temperature of the line entering the evaporator after the expansion valve. The low-pressure cycling switch usually has to be disconnected and a jumper wire used to connect the two electrical terminals allowing the compressor to run if the system is low on charge.
TECH TIP The Smell Test Many air-conditioning systems form mildew inside the evaporator housing due to the moist condition that exists in this area. If a “wet” smell is noticed, the mold and mildew may be the cause and a biocide will need to be used to correct the problem.
FIGURE 64–17 Typical electronic refrigerant leak detector. Many are capable of detecting either CFC-12 or HFC-134a.
TECH TIP Leak-Testing the Evaporator A quick-and-easy test to check whether the evaporator is leaking refrigerant is to remove the blower motor resistor pack. The blower motor resistor pack is almost always located directly “downstream” and near the blower motor. Removing the blower motor resistor pack gives access to the area near the evaporator. Inserting the probe of a leak detector into this open area allows the detector to test the air close to the evaporator. If the vehicle does not use a blower motor resistor or if it is difficult to access, hoist the vehicle and insert the sniffer probe in the condensate tube.
FIGURE 64–18 A black light being used to look for refrigerant leaks after a fluorescent dye was installed in the system.
Dye in the refrigerant. A dye is added to some refrigerant to help the technician visually spot a leak in the refrigerant system. This method works well except for leaks in the evaporator, which are usually not visible. SEE FIGURE 64–18.
Soap solution. Mix a few drops of liquid soap or detergent into a small glass of water. Using a small brush or a small spray bottle, apply the soapy solution to all fittings and other areas such as the condenser and compressor, which often are sources of leaks. If the system is empty, pressurize the system with dry nitrogen.
LEAK DETECTION
If the A/C system is low on a charge of refrigerant, the sources of the leak should be found and corrected. Several different methods of leak detection are available including:
Visual inspection. Look for oily areas that are formed when refrigerant leaks and some refrigerant oil is lost. It is this oil that indicates a refrigerant leak.
Electronic leak detector. Many of these units can detect both CFC-12 and HFC-134a. The detector will sound a tone if a leak is detected. SEE FIGURE 64–17.
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REVIEW QUESTIONS 1. Discuss how to diagnose the lack of heat from the heater. 2. Explain how the sight glass can be used to determine the state of charge.
3. List the various methods that can be used to detect refrigerant leaks.
CHAPTER QUIZ 1. A customer complains that the heater works sometimes, but sometimes only cold air comes out while driving. Technician A says that the water pump is defective. Technician B says that the cooling system could be low on coolant. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
6. Nothing is seen in the sight glass. Technician A says that the system may be completely empty of refrigerant. Technician B says that the system may be completely charged. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
2. Airflow through a typical HVAC system is being discussed. Technician A says that outside air is always used in all heating and cooling positions. Technician B says that the temperature is controlled by blending airflow through the evaporator and heater core. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
7. Technician A says that evaporator leaks can be detected by installing dye into the system and looking for yellowish-green dye stains. Technician B says that a leak at the evaporator can be detected by removing the blower motor resistor pack and inserting an electronic leak detector probe into the air stream. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
3. The first step in the diagnostic procedure when attempting to solve an HVAC customer problem is ______. a. Visual inspection b. Check for diagnostic trouble codes c. Check for technical service bulletins d. Verify customer concern 4. The last step in the diagnostic procedure is ______. a. Determine the root cause b. Verify the repair c. Recharge the system d. Perform a visual inspection 5. Technician A says that one heater hose should be hot and the other hose cool if the heater is functioning okay. Technician B says that both hoses should be hot to the touch. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B
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8. Technician A says that with a properly operating air-conditioning system, the inlet to the compressor should be cold and the outlet from the compressor hot. Technician B says that the condenser should be hot and the evaporator cold. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 9. A clogged orifice tube can cause a lack of cooling. a. True b. False 10. What must the technician do before checking an air-conditioning system for refrigerant leaks using a black light? a. Evacuate the system b. Install dye in the system c. Overcharge the system by 10 oz d. Turn the system off and allow the pressure to equalize
HEATING AND AIRCONDITIONING SYSTEM SERVICE
OBJECTIVES: After studying Chapter 65, the reader will be able to: • Prepare for the ASE A/C system service, diagnosis, and repair (A7) certification test content area “A”. • Perform heating, ventilation, and air-conditioning (HVAC) system service procedures. • Identify precautions that should be adhered to during HVAC system service. • Discuss proper evacuation and refrigerant recovery procedures. • List the steps needed to be performed to retrofit an older R-12 system to R-134a. • Describe air-conditioning parts replacement and service procedures. KEY TERMS: Air dam 746 • Fin comb 752 • Noncondensable gas 748 • O-ring seal 747 • Quick-disconnect valve 748 • Schrader valve 748 • Service cap 748
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BLOWER MOTOR SERVICE Blower motor related services include the following components and operation:
Blower motor and construction. If the blower motor is not functioning, the switch, resistors, or blower motor itself may need to be replaced. If the resistors are found to be defective, then double-check that the current draw of the blower motor is within factory specifications. One of the most common reasons for a defective blower motor resistor is a defective blower motor that has worn bushings and draws more than normal current (amperes).
Relays and switches. Switches and relays can be tested by proper operation and replaced if needed. Always follow the vehicle manufacturer’s recommended replacement procedures.
Mechanical, electrical, and vacuum components. Electrical wiring or terminals can often be repaired. Check service information for the recommended procedures to follow. If a component has been found to be defective, follow the vehicle manufacturer’s recommended component replacement procedures.
FIGURE 65–1 Some heater hoses are best inspected by hoisting the vehicle and inspecting them from underneath the vehicle as shown.
See Chapter 59 for details on blower motor diagnosis. TECH TIP
COOLING SYSTEM SERVICE COOLING SYSTEM THERMOSTAT REPLACEMENT A defective (stuck open) thermostat can cause a lack of heat from the heater. If heat “comes and goes,” check for proper coolant level in the radiator before replacing the thermostat. When replacing the thermostat, always follow the vehicle manufacturer’s recommended procedures and use the designated coolant. HEATER HOSE REPLACEMENT
Check heater hoses for signs of deterioration and replace as needed. SEE FIGURE 65–1. Follow the vehicle manufacturer’s recommended procedures.
COOLING FAN Inspect the cooling fan for dents, nicks, or other faults that can cause a vibration or reduce airflow through the radiator. Check the viscous fan clutch for leakage of silicone fluid and replace if needed. See chapter 21 for details on cooling fan-relayed diagnosis and service procedures.
REFRIGERANT RECOVERY PROCEDURES
Use the Same Length Heater Hoses Heater hoses are designed to supply warm coolant from the engine’s cooling system to the small radiator called the heater core inside the vehicle. Because the heater hoses attach to the engine and the engine moves on its mounts during operation, the heater hoses are long enough to allow the engine to move without causing stress to be applied to the heater core. The extra length also helps to prevent engine vibration from being transmitted to the heater core and the interior of the vehicle. When replacing heater hoses, always use the old hoses as a guide and use the same length hoses. Also, route the replacement hoses in the same manner as originally designed, again, to help reduce the stress to the heater core.
TECH TIP Check the Air Dam If Overheating Occurs The air dam under the front of the vehicle is designed to force air to flow upward and through the radiator rather than travel underneath the vehicle. If this air dam is broken or damaged due to contact with a parking block or other object, the engine may overheat.
LEAK REPAIR PROCEDURES
After a leak has been found, the refrigerant should be recovered and the faulty part repaired or replaced. Leaks at joints may need a replacement O-ring. Often, the leak is at a component such as the evaporator, condenser, or refrigerant line. Leaking components are usually replaced rather than repaired.
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REFRIGERANT RECOVERY Refrigerant should be recovered and not allowed to be discharged into the atmosphere. A refrigerant recovery unit should be used to remove the refrigerant from the vehicle, and it should be stored in a container until it can be recycled. SEE FIGURES 65–2 AND 65–3.
(a) (a)
(b)
FIGURE 65–2 (a) A typical automotive air-conditioning service machine that is capable of handling both CFC-12 and HFC-134a systems. (b) HFC-134a systems use quick-disconnect fittings that are larger than those used for CFC-12 systems. (b)
REFRIGERANT IDENTIFICATION
All refrigerant should be identified before it is recovered. Many also can detect sealers that may have been used in an attempt to stop a refrigerant leak. Sealers in refrigerant would contaminate the refrigerant and make it unsuitable for recycling. Always follow the operating instructions for machine being used. Most recovery units are capable of drawing a slight vacuum on the system (about 5 in. Hg) to assure that all refrigerant is removed from the system. During the recovery process, any refrigerant oil removed is separated from the refrigerant and allowed to flow into a container where it can be measured. This is important because the correct total amount of lubricating refrigerant oil must be added to the system when recharged to protect the compressor.
REPAIRS OR REPLACEMENT OF COMPONENTS
After all refrigerant has been removed from the system, repairs can be accomplished. For example, the evaporator can now be removed from the vehicle and replaced. If the system has been opened to the atmosphere for a length of time (over 24 hours), most experts recommend replacing the drier to help prevent the possibility of damaging moisture being trapped in the system. After all repairs are completed, the system should then be evacuated. NOTE: Be sure to follow all instructions regarding the amount of oil that needs to be added to the system if components have been replaced.
FIGURE 65–3 (a) Refrigerant oil must be retrieved and measured when the refrigerant is recovered from the system. (b) A rubber O-ring is used to indicate the level of refrigerant oil already in the container. The exact same amount of refrigerant oil must be installed as was removed when the system is recharged.
REFRIGERANT LINE CONNECTIONS Refrigerant lines have connections at each end so they can be removed during system repair. Refrigerant line connections must meet three requirements:
The connection must be vapor tight.
The connection must be easy to disconnect and reconnect.
The seals must withstand rapid and extreme temperature changes.
The O-ring seal, FIGURE 65–4, is part of a fitting that holds the ends of two refrigerant lines or hoses together inside a connector. The O-ring forms the seal between the lines or hoses and the connector. The O-rings usually are made of highly saturated nitriles (HSN) or neoprene rubber and remain flexible over a wide range of temperatures. The O-ring must be lubricated with clean refrigerant oil before assembly to ensure a good seal. Be careful not to crimp the O-ring during installation. Replace the O-ring seals at all connections when you retrofit a system to R-134a. This ensures any traces of R-12 or its oil
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O-RING
TUBE
TUBE
FIGURE 65–4 O-rings are usually made of neoprene rubber or highly saturated nitriles (HSN) to withstand high temperatures and flexing. O-rings should be changed during a retrofit procedure.
FEMALE FITTING
MALE FITTING
GARTER SPRING
on R-134a systems. Each type of refrigerant has its own unique fitting. This prevents accidental use of the wrong service equipment and/or the introduction of the wrong refrigerant. Service valves are found almost anywhere on the system. They may be located on the receiver-drier, accumulator, compressor, muffler, or in the lines themselves. All service valves have plastic coverings called service caps. SEE FIGURE 65–7. Along with preventing dirt from entering the system, service valve caps have O-rings which become the primary seal if a valve leaks. Always reattach the caps after any service has been performed, and replace them if you come across a system with missing service caps. Another built-in precaution is the refrigerant cut-off valve, which keeps the refrigerant in the service hose instead of allowing it to vent to the atmosphere. All service equipment hoses are required to have a cut-off valve within 12 inches of the end of the hose.
SCHRADER VALVES
O-RINGS
CAGE
FIGURE 65–5 A Ford spring-lock coupling.
SLIDE TOOL BACK AND OPEN COUPLER
FIT TOOL TOOL
REMOVE TOOL AND SEPARATE COUPLER
For years, R-12 systems have used the Schrader valve. A Schrader valve is similar to a tire valve. Internal pressure holds Schrader valves closed. There is also a small spring to keep the valve seated if the internal pressure becomes insufficient. When the service connection is made, the depressor in the end of the service hose or service coupling, presses on a small pin inside the valve, forcing the valve open. SEE FIGURE 65–8. The valve opens only when the service line connection is nearly complete, preventing contamination of the system or the unnecessary release of refrigerant. The high-side service valve on R-12 systems is smaller and has different threads than the low-side service valve. This prevents incorrect connections that may result in damage to the system and to your service equipment. Some Ford systems use different sizes of quick-disconnect fittings, similar to an air-hose coupling. Adapters are available for use with standard manifold gauge sets.
CASE OPENING
FIGURE 65–6 A special tool is needed to remove and install the Ford spring-lock coupling.
SAFETY TIP Refrigerant Can Be Hazardous Always wear safety glasses and protective gloves when servicing any automotive air-conditioning system. If any refrigerant escapes, it can cause skin to freeze or cause blindness if liquid refrigerant were to get into the eyes.
absorbed in the O-ring cannot enter the new system. Replace all gaskets as well. A variation on the O-ring seal is Ford’s spring-lock coupling. SEE FIGURE 65–5. It uses two O-rings mounted on the small end of the refrigeration line. The end of the joining refrigeration line is flared to slide over the two O-rings. A circular garter spring holds the connection together. You need a special tool to disconnect the coupling. SEE FIGURE 65–6.
SERVICE VALVES Service valves provide entry to the system when it is necessary to add or discharge refrigerant. The Schrader valve is used on R-12 systems. Quick-disconnect valves are used
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EVACUATION PROCEDURES Evacuation means that a vacuum will be applied to the system to vaporize any moisture that may be in the system. Although water boils at 212°F (100°C) at sea level, it can boil at much lower temperatures when the pressure is reduced. In other words, if a vacuum is applied to the air-conditioning system, the low pressure will cause any trapped moisture in the system to vaporize (boil). This water vapor is then removed from the system through the vacuum pump and released into the atmosphere. It is important to evacuate the system to at least 26 in. Hg of vacuum for at least 45 minutes to be assured that all of the moisture has been removed. For best results, the vacuum should be higher than 29 in. Hg. Just remember, the higher the vacuum and the longer that it is allowed to evacuate, the better.
NONCONDENSABLE GASES Refrigerant should be checked for the presence of air, which is called a noncondensable gas. This means that the air will not condense into a liquid when pressurized like refrigerant. If air is present in the container of refrigerant, it is considered to be a contaminate and will reduce the cooling efficiency if installed into an air-conditioning
O-RING O-RING
R-12 HIGH-PRESSURE SERVICE VALVE
R-134a HIGH-PRESSURE SERVICE VALVE
O-RING O-RING
R-12 LOW-PRESSURE SERVICE VALVE
R-134a LOW-PRESSURE SERVICE VALVE
FIGURE 65–7 The service cap O-ring becomes the primary seal if the service valve leaks.
TECH TIP Use a Micron Vacuum Gauge for Best Results A typical vacuum gauge reads in inches of Mercury (in. Hg) and the recommended vacuum level needed to remove moisture from the system is considered to be 27 in. Hg or less. However, many experts recommend using a vacuum gauge that measures the amount of air remaining in the system. This type of gauge measures vacuum in microns. A micron is one millimeter of a meter and there are about 760,000 microns of air at atmospheric pressure. A vacuum reading of 29.72 in. Hg is about 5,000 microns. Many experts recommend that the micron level be 500 or less for best results. This is particularly important when evacuating a dual-climate control system where two evaporators are used and there are long lengths of refrigerant lines. SEE FIGURE 65–9.
system. There are two ways to determine if there is air (noncondensable gas) in the refrigerant, including:
Use a refrigerant identifier. Most refrigerant identifiers will display the amount of air present.
Measure the temperature and pressure of the refrigerant. Compare the measurement to a temperature/pressure chart.
If the only contaminate is air, it can be purged from the refrigerant. Always follow the instructions on the recycling machine for the procedure to follow.
REFRIGERANT RECYCLING After refrigerant has been recovered, it needs to be recycled for further use. Most air-conditioning machines include the ability to recycle the refrigerant to the following SAE J1991 specification:
Moisture—A maximum of 15 parts per million (ppm) by weight
Refrigerant oil—A maximum of 4,000 parts per million (ppm) by weight
Noncondensable gases (air)—A maximum of 330 parts per million (ppm) by weight
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GAUGE SET HOSE ASSEMBLY
DEPRESSOR AND SEALING PLATE
FIGURE 65–10 A typical under-hood sticker that identifies the refrigerant and the amount needed to change the system in kilograms (0.96 kg is equal to 0.44 pounds).
SCHRADER VALVE VALVE CORE GAUGE PORT VALVE CLOSED
FIGURE 65–8 A depressor pin on the gauge set opens the Schrader valve when the connection is almost completely tightened. This prevents accidental refrigerant discharge.
FIGURE 65–11 A temperature and humidity gauge is a useful tool for air-conditioning work. The higher the relative humidity, the more difficult it is for the air-conditioning system to lower the temperature inside the vehicle.
REAL WORLD FIX The Cadillac Story
FIGURE 65–9 An air-conditioning vacuum gauge that reads in microns.
RECHARGING A SYSTEM After the system has been evacuated, it can be recharged with refrigerant. Most vehicles have a placard or sticker that indicates the correct amount of refrigerant to use. SEE FIGURES 65–10 AND 65–11. Follow the operating instructions for the equipment you are using.
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When servicing an older Cadillac equipped with an automatic air-conditioning system (C-68), it was discovered that the compressor would not engage. The vehicle owner stated that a message had been warning him that the system was low on charge. The technician tightened a slightly loose Schrader valve and then added about one pound of R-12 to the system, yet the controller (computer) would not engage the clutch. The technician then remembered that if a diagnostic trouble code (DTC) has been set, the computer will not allow the compressor clutch to be engaged. This is a precaution to prevent possible compressor damage if the system is low on charge and not able to transfer the lubricating refrigerant oil through the system that the compressor needs for lubrication. The technician disconnected the negative (⫺) battery cable and waited several minutes and then reconnected it. After starting the engine and turning on the A/C controls, the compressor clutch engaged and the service technician was able to complete charging the system.
TECH TIP Because It Fits, Does Not Mean It Is Correct! Many air-conditioning systems use orifice tubes that look similar if not identical. They are usually color coded for identification. Always use the recommended orifice tube for the vehicle you are servicing. Some examples of the various colors and sizes available include: Make
Color
Orifice Size (Inches)
Chrysler
purple
0.0605
Ford
red
0.0605
Ford
orange
0.0560
Ford
brown
0.0470
Ford
green
0.0505
GM
yellow
0.0605
NOTE: Always use the specified amount of refrigerant. Reduced cooling can occur if the system is either undercharged or overcharged. Air-conditioning service is definitely not a situation where “more is better.” (a)
RETROFITTING A CFC-12 SYSTEM TO A HFC-134A SYSTEM Due to environmental and cost concerns, many service technicians are retrofitting (adapting) CFC-12 systems to HFC-134a systems. Whenever making the change, several tasks have to be performed, including:
Specific service fittings must be installed.
Retrofit labels must be attached to the vehicle in a visible location.
PAG or ester oil must be used instead of the mineral oil in a CFC-12 system.
A high-pressure shutoff switch must be installed that opens the compressor clutch circuit if the pressure exceeds 410 PSI. Other changes that may or may not be necessary include:
Replacing hoses
Replacing O-rings
Replacing the receiver-drier or accumulator
Replacing pressure switches and calibrating them for use with an HFC-134a system
Replacing the condenser or compressor as required by some vehicle manufacturers
All of the required parts necessary to retrofit a particular vehicle are often included in a kit for easy use. SEE FIGURE 65–12. When the system is recharged, the amount of HFC-134a is usually 90% of the CFC-12 amount minus 4 ounces. In other words, if 30 ounces is the normal charge of CFC-12, then 23 ounces of HFC-134a should be used (30 ounces ⫻ 90% ⫽ 27 ounces minus 4 ounces ⫽ 23 ounces).
(b)
FIGURE 65–12 (a) When a system is retrofitted from CFC-12 to HFC-134a, the proper service fittings have to be used to help assure that cross-contamination does not occur. (b) An underhood sticker is also installed indicating that the system was retrofitted to HFC-134a and when it was done and by whom.
COMPRESSOR SERVICE COMPRESSOR DRIVE BELT Always check the compressor drive belt(s) whenever servicing the air-conditioning system and replace as needed. If some chunks are missing from the belt ribs or pieces of rubber are embedded in the pulleys, a noise that is often misinterpreted as coming from a defective compressor can occur. COMPRESSOR CLUTCH SERVICE
If the compressor clutch has been slipping, it will be blue, indicating that excessive heat has
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FIGURE 65–13 A special tool is needed to remove and install the magnetic clutch on the air-conditioning compressor.
FIGURE 65–14 A fin comb is used to straighten the fins on the condenser to help increase airflow and heat transfer.
TECH TIP TECH TIP An Additional Filter Is Insurance If the air-conditioning compressor is found to be damaged mechanically, many experts recommend that an additional filter be installed in the refrigerant line to trap any debris that may have gotten into the system. This additional filter will help prevent the new compressor from being harmed by the debris as it circulates through the system.
Might as Well Do It Now Whenever an evaporator is being replaced, many service technicians also recommend that the heater core also be replaced. This is especially true if the vehicle had a neglected cooling system. Most heater cores are close to or even have to be removed to replace an evaporator. The only additional cost to the vehicle owner is the cost of the heater core itself.
CONDENSER SERVICE been generated by the slipping clutch. Replace the clutch and adjust the air gap according to service information instructions. SEE FIGURE 65–13. If replacement is needed, determine the quantity of oil that may be trapped in the old unit so that the proper amount can be added to the system after the new compressor has been installed.
COMPRESSOR REMOVAL If testing indicates that the airconditioning compressor has failed, it should be removed from the vehicle after all of the refrigerant has been evacuated from the system. The steps specified by service information usually include the following: STEP 1
Remove the refrigerant from the system.
STEP 2
Disconnect the compressor drive belt.
STEP 3
Disconnect sensors and compressor clutch wiring connections and label them if needed.
STEP 4
Disconnect the suction and discharge hoses.
STEP 5
Seal the hoses to help keep moisture and dirt from entering the system.
STEP 6
Remove the compressor mounting fasteners.
STEP 7
Drain and measure the refrigerant oil from the compressor.
STEP 8
Inspect the hoses, lines, fittings, O-rings, seals, muffler, and service valves for proper operation and repair or replace as needed as part of the compressor service.
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Inspect the condenser for airflow restriction and clean as needed. Often a “fin comb” is needed to straighten the fins of the condenser, which may have been bent by road debris. SEE FIGURE 65–14. If replacement is needed, determine the quantity of oil that may be trapped in the old unit so that the proper amount can be added to the system after the new condenser has been installed.
EVAPORATOR SERVICE If the evaporator has been tested and found to be clogged or leaking, it has to be replaced. In most vehicles this is a major job involving disassembly of the dash.
RECEIVER/DRIER OR ACCUMULATOR/ DRIER SERVICE Most experts recommend that the receiver/drier or accumulator/ drier be replaced anytime the refrigerant system is opened and other repairs or services are being performed. Before replacing
the receiver/drier or accumulator/drier, determine the quantity of refrigerant oil so that the proper amount can be added to the system when it is recharged. Always follow the vehicle manufacturer’s recommended service and repair procedures. SEE FIGURE 65–15.
ORIFICE TUBE/EXPANSION VALVE SERVICE
FIGURE 65–15 Always be sure that the service valves are snug before evacuating the system. They are a common place for small refrigerant leaks.
If the orifice tube is found to be clogged or the expansion valve has been determined to be not operating correctly, they will require replacement. Always follow the vehicle manufacturer’s recommended replacement procedures and adhere to all precautions.
REVIEW QUESTIONS 1. What components should be checked if a blower motor resistor is found to be defective?
4. Why should the receiver/drier or accumulator/drier be replaced if the refrigerant system is opened for a repair?
2. Why could a broken air dam in the front of a vehicle cause an engine to overheat?
5. What steps and procedures are required to retrofit an older R-12 system to a R-134a system?
3. Why should a refrigerant identifier be used before evacuating the refrigerant?
CHAPTER QUIZ 1. A customer complains that the heater works sometimes, but sometimes only cold air comes out while driving. Technician A says that the water pump is defective. Technician B says that the cooling system could be low on coolant. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 2. Two technicians are discussing replacing heater hoses. Technician A says that the replacement hoses should be the same length as the original hoses. Technician B says that the replacement hoses should be cut as short as possible to allow more coolant to flow through the heater core faster. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 3. A defective thermostat can cause the engine to operate ________. a. Too cold c. Either a or b b. Too hot d. Neither a nor b 4. O-rings are usually made from ________. a. HSN c. Neoprene b. Natural rubber d. Either a or c 5. What type of service valves are used with R-134a? a. Schrader valves c. Quick-disconnect valves b. Gate valves d. Saddle valves
6. Which reading represents the lowest vacuum reading? a. 27 in. Hg c. 29 in. Hg b. 28 in. Hg d. 500 microns 7. What is a noncondensable gas? a. Air c. Ozone b. R-12 d. R-134a 8. Technician A says that all orifice tubes on all vehicles use the same orifice size. Technician B says that orifice tubes vary the orifice size by application. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 9. Which part must be used when refitting a vehicle from R-12 to R-134a refrigerant? a. A new (larger) condenser b. A new service fitting and a retrofit label c. A high-pressure cut-off switch d. Both a and b 10. When replacing a compressor clutch, what is the critical measurement? a. Air gap b. Current (ampere) draw c. Voltage drop d. High-pressure pressure
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S E C T I O N
IX
Engine Performance
66 Gasoline
78 Fuel Injection Components and Operation
67 Alternative Fuels
79 Gasoline Direct Injection Systems
68 Diesel and Biodiesel Fuels
80 Electronic Throttle Control Systems
69 Ignition System Components and Operation
81 Fuel Injection System Diagnosis and Service
70 Ignition System Diagnosis and Service
82 Vehicle Emission Standards and Testing
71 Computer Fundamentals
83 Evaporative Emission Control Systems
72 Temperature Sensors
84 Exhaust Gas Recirculation (EGR) Systems
73 Throttle Position Sensors 74 MAP/BARO Sensors
85 Positive Crankcase Ventilation (PCV) and Secondary Air Injection (SAI) Systems
75 Mass Air Flow Sensors
86 Catalytic Converters
76 Oxygen Sensors
87 On-Board Diagnosis
77 Fuel Pumps, Lines, and Filters
88 Scan Tools and Engine Performance Diagnosis
chapter
GASOLINE
66 OBJECTIVES: After studying Chapter 66, the reader should be able to: • Describe how the proper grade of gasoline affects engine performance. • List gasoline purchasing hints. • Discuss how volatility affects driveability. • Explain how oxygenated fuels can reduce CO exhaust emissions. • Discuss safety precautions when working with gasoline. KEY TERMS: Air-fuel ratio 757 • American Society for Testing and Materials (ASTM) 756 • Antiknock index (AKI) 759 • British thermal unit (BTU) 757 • Catalytic cracking 755 • Cracking 755 • Detonation 758 • Distillation 755 • Distillation curve 756 • Driveability index (DI) 756 • E10 761 • Ethanol 761 • Fungible 756 • Gasoline 754 • Hydrocracking 755 • Octane rating 758 • Oxygenated fuels 760 • Petroleum 755 • Ping 758 • Reformulated gasoline (RFG) 762 • Reid vapor pressure (RVP) 756 • Spark knock 758 • Stoichiometric 758 • Tetraethyl lead (TEL) 757 • Vapor lock 756 • Volatility 756 • World Wide Fuel Charter (WWFC) 763
GASOLINE DEFINITION
Gasoline is a term used to describe a complex mixture of various hydrocarbons refined from crude petroleum oil for use as a fuel in engines. Gasoline and air burns in the cylinder of the engine and produces heat and pressure, which is converted to rotary motion inside the engine and eventually powers the drive wheels of a vehicle. When combustion occurs, carbon dioxide and water are produced if the process is perfect and all of the air and all of the fuel are consumed in the process.
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CHEMICAL COMPOSITION Gasoline is a combination of hydrocarbon molecules that have between five and 12 carbon atoms. The names of these various hydrocarbons are based on the number of carbon atoms and include:
Methane—one carbon atom
Ethane—two carbon atoms
Propane—three carbon atoms
Butane—four carbon atoms
Pentane—five carbon atoms
Hexane—six carbon atoms
SULFUR RECOVERY
SULFUR
FUEL GAS FOR REFINERY USE
LIGHT PETROLEUM GAS TREATING
PROPANE
BENZENE
AROMATICS
NAPTHA HYDROTREATING
CHEMICAL AND GASOLINE REFORMING
p-XYLENE
MOTOR GASOLINE
JET HYDROTREATING AVIATION GASOLINE
DIESEL HYDROTREATING GAS OIL HYDROCRACKING
JET ALKYLATION
CATALYTIC CRACKING
DIESEL
GAS OIL HYDROTREATING
BUNKER (SHIP FUEL)
RESIDUE PROCESSING
PETROLEUM COKE
DISTILLATION COLUMN
FIGURE 66–1 The crude oil refining process showing most of the major steps and processes.
Heptane—seven carbon atoms (Used to test octane rating– has an octane rating of zero)
Octane—eight carbon atoms (A type of octane is used as a basis for antiknock rating)
REFINING TYPES OF CRUDE OIL
Refining is a complex combination of interdependent processing units that can separate crude oil into useful products such as gasoline and diesel fuel. As it comes out of the ground, petroleum (meaning “rock oil”) crude can be as thin and light colored as apple cider or as thick and black as melted tar. A barrel of crude oil is 42 gallons, not 55 gallons as commonly used for industrial barrels. Typical terms used to describe the type of crude oil include:
Thin crude oil has a high American Petroleum Institute (API) gravity, and therefore, is called high-gravity crude. Thick crude oil is called low-gravity crude. High-gravity-type crude contains more natural gasoline and its lower sulfur and nitrogen content makes it easier to refine. Low-sulfur crude oil is also known as “sweet” crude. High-sulfur crude oil is also known as “sour” crude.
DISTILLATION
In the late 1800s, crude was separated into different products by boiling in a process called distillation. Distillation works because crude oil is composed of hydrocarbons with a broad range of boiling points.
In a distillation column, the vapor of the lowest-boiling hydrocarbons, propane and butane, rises to the top. The straight-run gasoline (also called naphtha), kerosene, and diesel fuel cuts are drawn off at successively lower positions in the column.
CRACKING Cracking is the process where hydrocarbons with higher boiling points could be broken down (cracked) into lowerboiling hydrocarbons by treating them to very high temperatures. This process, called thermal cracking, was used to increase gasoline production starting in 1913. Instead of high heat, today cracking is performed using a catalyst and is called catalytic cracking. A catalyst is a material that speeds up or otherwise facilitates a chemical reaction without undergoing a permanent chemical change itself. Catalytic cracking produces gasoline of higher quality than thermal cracking. Hydrocracking is similar to catalytic cracking in that it uses a catalyst, but the catalyst is in a hydrogen atmosphere. Hydrocracking can break down hydrocarbons that are resistant to catalytic cracking alone, and it is used to produce diesel fuel rather than gasoline. Other types of refining processes include:
Reforming
Alkylation
Isomerization
Hydrotreating
Desulfurization
SEE FIGURE 66–1. GA S OL IN E
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FREQUENTLY ASKED QUESTION
Why Do I Get Lower Gas Mileage in the Winter? Several factors cause the engine to use more fuel in the winter than in the summer, including:
FIGURE 66–2 A gasoline testing kit, including an insulated container where water at 100°F is used to heat a container holding a small sample of gasoline. The reading on the pressure gauge is the Reid vapor pressure (RVP).
• Gasoline that is blended for use in cold climates is designed for ease of starting and contains fewer heavy molecules, which contribute to fuel economy. The heat content of winter gasoline is lower than summer-blended gasoline. • In cold temperatures, all lubricants are stiff, causing more resistance. These lubricants include the engine oil, as well as the transmission and differential gear lubricants. • Heat from the engine is radiated into the outside air more rapidly when the temperature is cold, resulting in longer run time until the engine has reached normal operating temperature. • Road conditions, such as ice and snow, can cause tire slippage or additional drag on the vehicle.
SHIPPING
The gasoline is transported to regional storage facilities by railway tank car or by pipeline. In the pipeline method, all gasoline from many refiners is often sent through the same pipeline and can become mixed. All gasoline is said to be fungible, meaning that it is capable of being interchanged because each grade is created to specification so there is no reason to keep the different gasoline brands separated except for grade. Regular grade, mid-grade, and premium grades are separated in the pipeline and the additives are added at the regional storage facilities and then shipped by truck to individual gas stations.
VOLATILITY DEFINITION OF VOLATILITY
Volatility describes how easily the gasoline evaporates (forms a vapor). The definition of volatility assumes that the vapors will remain in the fuel tank or fuel line and will cause a certain pressure based on the temperature of the fuel.
REID VAPOR PRESSURE (RVP) Reid vapor pressure (RVP) is the pressure of the vapor above the fuel when the fuel is at 100°F (38°C). Increased vapor pressure permits the engine to start in cold weather. Gasoline without air will not burn. Gasoline must be vaporized (mixed with air) to burn in an engine. SEE FIGURE 66–2. SEASONAL BLENDING Cold temperatures reduce the normal vaporization of gasoline; therefore, winter-blended gasoline is specially formulated to vaporize at lower temperatures for proper starting and driveability at low ambient temperatures. The American Society for Testing and Materials (ASTM) standards for winter-blend gasoline allow volatility of up to 15 pounds per square inch (PSI) RVP. At warm ambient temperatures, gasoline vaporizes easily. However, the fuel system (fuel pump, carburetor, fuel-injector nozzles, etc.) is designed to operate with liquid gasoline. The volatility of summer-grade gasoline should be about 7.0 PSI RVP. According to ASTM standards, the maximum RVP should be 10.5 PSI for summer-blend gasoline. DISTILLATION CURVE Besides Reid vapor pressure, another method of classifying gasoline volatility is the distillation curve. A curve on a graph is created by plotting the temperature at which the various percentage of the fuel evaporates. A typical distillation curve is shown in FIGURE 66–3.
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DRIVEABILITY INDEX A distillation curve shows how much of a gasoline evaporates at what temperature range. To predict coldweather driveability, an index was created called the driveability index, also called the distillation index, and abbreviated DI. The DI was developed using the temperature for the evaporated percentage of 10% (labeled T10), 50% (labeled T50), and 90% (labeled T90). The formula for DI is: DI 1.5 T10 3 T50 T90 The total DI is a temperature and usually ranges from 1,000°F to 1,200°F. The lower values of DI generally result in good cold-start and warm-up performance. A high DI number is less volatile than a low DI number. NOTE: Most premium-grade gasoline has a higher (worse) DI than regular-grade or midgrade gasoline, which could cause poor cold-weather driveability. Vehicles designed to operate on premium-grade gasoline are programmed to handle the higher DI, but engines designed to operate on regular-grade gasoline may not be able to provide acceptable cold-weather driveability.
VOLATILITY-RELATED PROBLEMS At higher temperatures, liquid gasoline can easily vaporize, which can cause vapor lock. Vapor lock is a lean condition caused by vaporized fuel in the fuel system. This vaporized fuel takes up space normally occupied by liquid fuel. Bubbles that form in the fuel cause vapor lock, preventing proper operation of the fuel-injection system. Heat causes some fuel to evaporate, thereby causing bubbles. Sharp bends cause the fuel to be restricted at the bend. When the fuel flows past the bend, the fuel can expand to fill the space after the bend. This expansion drops the pressure, and bubbles form in the fuel lines. When the fuel is full of bubbles, the engine is not being supplied with enough fuel and the engine runs lean. A lean engine will stumble during acceleration, will run rough, and may stall. Warm weather and alcohol-blended fuels both tend to increase vapor lock and engine performance problems. If winter-blend gasoline (or high-RVP fuel) is used in an engine during warm weather, the following problems may occur: 1. Rough idle 2. Stalling 3. Hesitation on acceleration 4. Surging
TAIL END
MIDRANGE
FRONT END
TEMPERATURE
˚F
400
RESIDUE (LESS THAN 2.7)
300
DILUTION OF ENGINE OIL
200
CRANKCASE DEPOSITS SPARK PLUG FOULING COMBUSTION CHAMBER DEPOSITS
100 WARM-UP AND COOL WEATHER DRIVEABILITY EASY COLD STARTING
SHORT TRIP ECONOMY
0
0
20
40
60
80
100
EVAPORATED % FIGURE 66–3 A typical distillation curve. Heavier molecules evaporate at higher temperatures and contain more heat energy for power, whereas the lighter molecules evaporate easier for starting.
GASOLINE COMBUSTION PROCESS CHEMICAL REACTIONS The combustion process involves the chemical combination of oxygen (O2) from the air (about 21% of the atmosphere) with the hydrogen and carbon from the fuel. In a gasoline engine, a spark starts the combustion process, which takes about 3 ms (0.003 sec) to be completed inside the cylinder of an engine. The chemical reaction that takes place can be summarized as follows: hydrogen (H) plus carbon (C) plus oxygen (O2) plus nitrogen (N) plus spark equals heat plus water (H2O) plus carbon monoxide (CO) (if incomplete combustion) plus carbon dioxide (CO2) plus hydrocarbons (HC) plus oxides of nitrogen (NOX) plus many other chemicals. In an equation format it looks like this: H C ⫹ O2 ⫹ N ⫹ Spark ⫽ Heat ⫹ CO2 ⫹ HC ⫹ NOX
HEAT ENERGY The heat produced by the combustion process is measured in British thermal units (BTUs). One BTU is the amount of heat required to raise one pound of water one Fahrenheit degree. The metric unit of heat is the calorie (cal). One calorie is the amount of heat required to raise the temperature of one gram (g) of water one Celsius degree: Gasoline—About 130,000 BTUs per gallon
18.5:1
STALL – MIXTURE TOO LEAN
BEST MIXTURE 14.7:1
RUNNING RANGE STALL – MIXTURE TOO RICH
8.0:1
FIGURE 66–4 An engine will not run if the air-fuel mixture is either too rich or too lean.
AIR-FUEL RATIOS
Fuel burns best when the intake system turns it into a fine spray and mixes it with air before sending it into the cylinders. In fuel-injected engines, the fuel becomes a spray and mixes with the air in the intake manifold. There is a direct relationship between engine airflow and fuel requirements; this is called the air-fuel ratio. The air-fuel ratio is the proportion by weight of air and gasoline that the injection system mixes as needed for engine combustion. The mixtures, with which an engine can operate without stalling, range from 8 to 1 to 18.5 to 1. SEE FIGURE 66–4.
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These ratios are usually stated by weight, such as:
8 parts of air by weight combined with 1 part of gasoline by weight (8:1), which is the richest mixture that an engine can tolerate and still fire reliably.
18.5 parts of air mixed with 1 part of gasoline (18.5:1), which is the leanest practical ratio. Richer or leaner air-fuel ratios cause the engine to misfire badly or not run at all.
STOICHIOMETRIC AIR-FUEL RATIO
The ideal mixture or ratio at which all of the fuel combines with all of the oxygen in the air and burns completely is called the stoichiometric ratio, a chemically perfect combination. In theory, this ratio for gasoline is an airfuel mixture of 14.7 to 1. SEE FIGURE 66–5. CO CONVERSION EFFICIENCY (%)
100 NOx
80
HC THREE-WAY CATALYST OPERATING RANGE
60
40
20
RICH A–F MIXTURE
0 13:1
LEAN A–F MIXTURE
14:1 14.7:1 15:1 AIR–FUEL (A–F) RATIO
16:1
FIGURE 66–5 With a three-way catalytic converter, emission control is most efficient with an air-fuel ratio between 14.65 to 1 and 14.75 to 1.
COMPRESSION
IGNITION
In reality, the exact ratio at which perfect mixture and combustion occurs depends on the molecular structure of gasoline, which can vary. The stoichiometric ratio is a compromise between maximum power and maximum economy.
NORMAL AND ABNORMAL COMBUSTION The octane rating of gasoline is the measure of its antiknock properties. Engine knock (also called detonation, spark knock, or ping) is a metallic noise an engine makes, usually during acceleration, resulting from abnormal or uncontrolled combustion inside the cylinder. Normal combustion occurs smoothly and progresses across the combustion chamber from the point of ignition. SEE FIGURE 66–6. Normal flame-front combustion travels between 45 and 90 mph (72 and 145 km/h). The speed of the flame front depends on the air-fuel ratio, combustion chamber design (determining amount of turbulence), and temperature. During periods of spark knock (detonation), the combustion speed increases by up to 10 times to near the speed of sound. The increased combustion speed also causes increased temperatures and pressures, which can damage pistons, gaskets, and cylinder heads. SEE FIGURE 66–7. One of the first additives used in gasoline was tetraethyl lead (TEL). TEL was added to gasoline in the early 1920s to reduce the tendency to knock. It was often called ethyl or high-test gasoline.
COMBUSTION
COMBUSTION CONTINUED
COMBUSTION COMPLETED
FIGURE 66–6 Normal combustion is a smooth, controlled burning of the air-fuel mixture.
COMPRESSION
SPARK IGNITION
COMBUSTION
COMBUSTION CONTINUED
DETONATION
FIGURE 66–7 Detonation is a secondary ignition of the air-fuel mixture. It is also called spark knock or pinging.
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FREQUENTLY ASKED QUESTION
What Grade of Gasoline Does the EPA Use When Testing Engines? Due to the various grades and additives used in commercial fuel, the government (EPA) uses a liquid called indolene. Indolene has a research octane number of 96.5 and a motor method octane rating of 88, which results in an R M 2 rating of 92.25.
TECH TIP Horsepower and Fuel Flow To produce 1 hp, the engine must be supplied with 0.50 lb of fuel per hour (lb/hr). Fuel injectors are rated in pounds per hour. For example, a V-8 engine equipped with 25 lb/hr fuel injectors could produce 50 hp per cylinder (per injector) or 400 hp. Even if the cylinder head or block is modified to produce more horsepower, the limiting factor may be the injector flow rate. The following are flow rates and resulting horsepower for a V-8 engine: 30 lb/hr: 60 hp per cylinder or 480 hp 35 lb/hr: 70 hp per cylinder or 560 hp 40 lb/hr: 80 hp per cylinder or 640 hp Of course, injector flow rate is only one of many variables that affect power output. Installing larger injectors without other major engine modification could decrease engine output and drastically increase exhaust emissions.
OCTANE RATING The antiknock standard or basis of comparison is the knockresistant hydrocarbon isooctane, chemically called trimethylpentane (C8H18), also known as 2-2-4 trimethylpentane. If a gasoline tested had the exact same antiknock characteristics as isooctane, it was rated as 100-octane gasoline. If the gasoline tested had only 85% of the antiknock properties of isooctane, it was rated as 85 octane. Remember, octane rating is only a comparison test. The two basic methods used to rate gasoline for antiknock properties (octane rating) are the research method and the motor method. Each uses a model of the special cooperative fuel research (CFR) singlecylinder engine. The research method and the motor method vary as to temperature of air, spark advance, and other parameters. The research method typically results in readings that are 6 to 10 points higher than those of the motor method. For example, a fuel with a research octane number (RON) of 93 might have a motor octane number (MON) of 85. The octane rating posted on pumps in the United States is the average of the two methods and is referred to as (R M) 2, meaning that, for the fuel used in the previous example, the rating posted on the pumps would be RON 1 MON 93 1 85 ⴝ 5 89 2 2 The pump octane is called the antiknock index (AKI).
FIGURE 66–8 A pump showing regular with a pump octane of 87, plus rated at 89, and premium rated at 93. These ratings can vary with brand as well as in different parts of the country.
GASOLINE GRADES AND OCTANE NUMBER
The posted octane rating on gasoline pumps is the rating achieved by the average of the research and the motor methods. SEE FIGURE 66–8. Except in high-altitude areas, the grades and octane ratings are as follows:
Grades
Octane rating
Regular
87
Midgrade (also called Plus)
89
Premium
91 or higher
HIGH-ALTITUDE OCTANE SAFETY IN LIFTING REQUIREMENTS (HOISTING) A VEHICLE As the altitude increases, atmospheric pressure drops. The air is less dense because a pound of air takes more volume. The octane rating of fuel does not need to be as high because the engine cannot take in as much air. This process will reduce the combustion (compression) pressures inside the engine. In mountainous areas, gasoline (R M) 2 octane ratings are two or more numbers lower than normal (according to the SAE, about one octane number lower per 1,000 ft or 300 m in altitude). SEE FIGURE 66–9. A secondary reason for the lowered octane requirement of engines running at higher altitudes is the normal enrichment of the air-fuel ratio and lower engine vacuum with the decreased air density. Some problems, therefore, may occur when driving out of highaltitude areas into lower-altitude areas where the octane rating must be higher. Most computerized engine control systems can compensate for changes in altitude and modify air-fuel ratio and ignition timing for best operation. Because the combustion burn rate slows at high altitude, the ignition (spark) timing can be advanced to improve power. The amount of timing advance can be about 1 degree per 1,000 ft over 5,000 ft. Therefore, if driving at 8,000 ft of altitude, the ignition timing can be advanced 3 degrees. High altitude also allows fuel to evaporate more easily. The volatility of fuel should be reduced at higher altitudes to prevent vapor from forming in sections of the fuel system, which can cause driveability and stalling problems. The extra heat generated in climbing
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FREQUENTLY ASKED QUESTION
What Is Meant by “Phase Separation?” All alcohols absorb water, and the alcohol–water mixture can separate from the gasoline and sink to the bottom of the fuel tank. This process is called phase separation. To help avoid engine performance problems, try to keep at least a quarter tank of fuel at all times, especially during seasons when there is a wide temperature span between daytime highs and nighttime lows. These conditions can cause moisture to accumulate in the fuel tank as a result of condensation of the moisture in the air.
FIGURE 66–9 The posted octane rating in most high-altitude areas shows regular at 85 instead of the usual 87.
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OCTANE IMPROVER ADDITIVES FREQUENTLY ASKED QUESTION
Can Regular-Grade Gasoline Be Used If Premium Is the Recommended Grade? Maybe. It is usually possible to use regular-grade or midgrade (plus) gasoline in most newer vehicles without danger of damage to the engine. Most vehicles built since the 1990s are equipped with at least one knock sensor. If a lower octane gasoline than specified is used, the engine ignition timing setting will usually cause the engine to spark knock, also called detonation or ping. This spark knock is detected by the knock sensor(s), which sends a signal to the computer. The computer then retards the ignition timing until the spark knock stops. NOTE: Some scan tools will show the “estimated octane rating” of the fuel being used, which is based on knock sensor activity. As a result of this spark timing retardation, the engine torque is reduced. While this reduction in power is seldom noticed, it will reduce fuel economy, often by 4 to 5 miles per gallon. If premium gasoline is then used, the PCM will gradually permit the engine to operate at the more advanced ignition timing setting. Therefore, it may take several tanks of premium gasoline to restore normal fuel economy. For best overall performance, use the grade of gasoline recommended by the vehicle manufacturer.
to higher altitudes plus the lower atmospheric pressure at higher altitudes combine to cause vapor lock problems as the vehicle goes to higher altitudes.
GASOLINE ADDITIVES DYE
Dye is usually added to gasoline at the distributor to help identify the grade and/or brand of fuel. In many countries, fuels are required to be colored using a fuel-soluble dye. In the United States and Canada, diesel fuel used for off-road use and not taxed is re-
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quired to be dyed red for identification. Gasoline sold for off-road use in Canada is dyed purple.
CHAPTER 66
When gasoline companies, under federal EPA regulations, removed tetraethyl lead from gasoline, other methods were developed to help maintain the antiknock properties of gasoline. Octane improvers (enhancers) can be grouped into three broad categories: 1. Aromatic hydrocarbons (hydrocarbons containing the benzene ring) such as xylene and toluene 2. Alcohols such as ethanol (ethyl alcohol), methanol (methyl alcohol), and tertiary butyl alcohol (TBA) 3. Metallic compounds such as methylcyclopentadienyl manganese tricarbonyl (MMT) NOTE: MMT has been proven to be harmful to catalytic converters and can cause spark plug fouling. However, MMT is currently one of the active ingredients commonly found in octane improvers available to the public and in some gasoline sold in Canada. If an octane boost additive has been used that contains MMT, the spark plug porcelain will be rust colored around the tip. Propane and butane, which are volatile by-products of the refinery process, are also often added to gasoline as octane improvers. The increase in volatility caused by the added propane and butane often leads to hot-weather driveability problems.
OXYGENATED FUEL ADDITIVES Oxygenated fuels contain oxygen in the molecule of the fuel itself. Examples of oxygenated fuels include methanol, ethanol, methyl tertiary butyl ether (MTBE), tertiary-amyl methyl ether (TAME), and ethyl tertiary butyl ether (ETBE). Oxygenated fuels are commonly used in high-altitude areas to reduce carbon monoxide (CO) emissions. The extra oxygen in the fuel itself is used to convert harmful CO into carbon dioxide (CO2). The extra oxygen in the fuel helps ensure that there is enough oxygen to convert all CO into CO2 during the combustion process in the engine or catalytic converter. METHYL TERTIARY BUTYL ETHER (MTBE). MTBE is manufactured by means of the chemical reaction of methanol and isobutylene. Unlike methanol, MTBE does not increase the volatility of the fuel and is not as sensitive to water as are other alcohols. The maximum allowable volume level, according to the EPA, is 15% but is currently being phased out because of health concerns, as well as MTBE contamination of drinking water if spilled from storage tanks.
GAS & ETHANOL
FIGURE 66–12 In-line blending is the most accurate method for blending ethanol with gasoline because computers are used to calculate the correct ratio.
ETHANOL
GAS
FIGURE 66–10 This refueling pump indicates that the gasoline is blended with 10% ethanol (ethyl alcohol) and can be used in any gasoline vehicle. E85 contains 85% ethanol and can be used only in vehicles specifically designed to use it.
OL N ET H A G A S
FIGURE 66–13 Sequential blending uses a computer to calculate the correct ratio as well as the prescribed order in which the products are loaded.
ETHANOL
GAS
FIGURE 66–14 Splash blending occurs when the ethanol is added to a tanker with gasoline and is mixed as the truck travels to the retail outlet.
FIGURE 66–11 A container with gasoline containing alcohol. Notice the separation line where the alcohol–water mixture separated from the gasoline and sank to the bottom.
TERTIARY-AMYL METHYL ETHER. Tertiary-amyl methyl ether (TAME) contains an oxygen atom bonded to two carbon atoms and is added to gasoline to provide oxygen to the fuel. It is slightly soluble in water, very soluble in ethers and alcohol, and soluble in most organic solvents including hydrocarbons. ETHYL TERTIARY BUTYL ETHER. ETBE is derived from ethanol. The maximum allowable volume level is 17.2%. The use of ETBE is the cause of much of the odor from the exhaust of vehicles using reformulated gasoline. ETHANOL. Ethanol, also called ethyl alcohol is drinkable alcohol and is usually made from grain. Adding 10% ethanol (ethyl alcohol or grain alcohol) increases the (R M) 2 octane rating by three points. The alcohol added to the base gasoline, however, also raises the volatility of the fuel about 0.5 PSI. Most automobile manufacturers permit up to 10% ethanol if driveability problems are not experienced. The oxygen content of a 10% blend of ethanol in gasoline, called E10, is 3.5% oxygen by weight. SEE FIGURE 66–10. Keeping the fuel tank full reduces the amount of air and moisture in the tank. SEE FIGURE 66–11.
GASOLINE BLENDING Gasoline additives, such as ethanol and dyes, are usually added to the fuel at the distributor. Adding ethanol to gasoline is a way to add oxygen to the fuel itself. Gasoline containing an addition that has oxygen is called oxygenated fuel. There are three basic methods used to blend ethanol with gasoline to create E10 (10% ethanol, 90% gasoline): 1. In-line blending. Gasoline and ethanol are mixed in a storage tank or in the tank of a transport truck while it is being filled. Because the quantities of each can be accurately measured, this method is most likely to produce a well-mixed blend of ethanol and gasoline. SEE FIGURE 66–12. 2. Sequential blending. This method is usually performed at the wholesale terminal and involves adding a measured amount of ethanol to a tank truck followed by a measured amount of gasoline. SEE FIGURE 66–13. 3. Splash blending. Splash blending can be done at the retail outlet or distributor and involves separate purchases of ethanol and gasoline. In a typical case, a distributor can purchase gasoline, and then drive to another supplier and purchase ethanol. The ethanol is then added (splashed) into the tank of gasoline. This method is the least-accurate method of blending and can result in ethanol concentration for E10 that should be 10% to range from 5% to over 20% in some cases. SEE FIGURE 66–14.
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FIGURE 66–15 Checking gasoline for alcohol involves using a graduated cylinder and adding water to check if the alcohol absorbs the water.
COLLECT 90 ml of GASOLINE
100
100
100
90
90
90
80
80
80
70
70
70
60
60
60
50
50
50
40
40
40
30
30
20 10 0
STEP 1
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FREQUENTLY ASKED QUESTION
20
ADD 10 ml of WATER
10
30
ALCOHOL WILL ABSORB THE WATER
20 10
0
0
STEP 2
STEP 3
reformulated gasoline is being used. Formaldehyde is formed when RFG is burned, and the vehicle exhaust has a unique smell when reformulated gasoline is used.
Is Water Heavier Than Gasoline? Yes. Water weighs about 8.3 pounds per gallon, whereas gasoline weighs about 6 pounds per gallon. The density as measured by specific gravity includes: Water 1.000 (the baseline for specific gravity) Gasoline 0.730 to 0.760 This means that any water that gets into the fuel tank will sink to the bottom.
TESTING GASOLINE FOR ALCOHOL CONTENT Take the following steps when testing gasoline for alcohol content:
WARNING
REFORMULATED GASOLINE Reformulated gasoline (RFG) is manufactured to help reduce emissions. The gasoline refiners reformulate gasoline by using additives that contain at least 2% oxygen by weight and reducing the additive benzene to a maximum of 1% by volume. Two other major changes done at the refineries are as follows:
Do not smoke or run the test around sources of ignition!
1. Pour suspect gasoline into a graduated cylinder. 2. Carefully fill the graduated cylinder to the 90-mL mark. 3. Add 10 mL of water to the graduated cylinder by counting the number of drops from an eyedropper.
1. Reduce light compounds. Refineries eliminate butane, pentane, and propane, which have a low boiling point and evaporate easily. These unburned hydrocarbons are released into the atmosphere during refueling and through the fuel tank vent system, contributing to smog formation. Therefore, reducing the light compounds from gasoline helps reduce evaporative emissions.
4. Put the stopper in the cylinder and shake vigorously for 1 minute. Relieve built-up pressure by occasionally removing the stopper. Alcohol dissolves in water and will drop to the bottom of the cylinder.
2. Reduce heavy compounds. Refineries eliminate heavy compounds with high boiling points such as aromatics and olefins. The purpose of this reduction is to reduce the amount of unburned hydrocarbons that enter the catalytic converter, which makes the converter more efficient, thereby reducing emissions.
7. For percent of alcohol in gasoline, subtract 10 from the reading.
Because many of the heavy compounds are eliminated, a drop in fuel economy of about 1 mpg has been reported in areas where
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5. Place the cylinder on a flat surface and let it stand for 2 minutes. 6. Take a reading near the bottom of the cylinder at the boundary between the two liquids. For example, The reading is 20 mL: 20 10 10% alcohol If the increase in volume is 0.2% or less, it may be assumed that the test gasoline contains no alcohol. SEE FIGURE 66–15. Alcohol content can also be checked using an electronic tester. See the step-by-step sequence at the end of the chapter.
TECH TIP The Sniff Test Problems can occur with stale gasoline from which the lighter parts of the gasoline have evaporated. Stale gasoline usually results in a no-start situation. If stale gasoline is suspected, sniff it. If it smells rancid, replace it with fresh gasoline. NOTE: If storing a vehicle, boat, or lawnmower over the winter, put some gasoline stabilizer into the gasoline to reduce the evaporation and separation that can occur during storage. Gasoline stabilizer is frequently available at lawnmower repair shops or marinas. FIGURE 66–16 The gas cap on a Ford vehicle notes that BP fuel is recommended.
? ?
FREQUENTLY ASKED QUESTION
How Does Alcohol Content in the Gasoline Affect Engine Operation? In most cases, the use of gasoline containing 10% or less of ethanol (ethyl alcohol) has little or no effect on engine operation. However, because the addition of 10% ethanol raises the volatility of the fuel slightly, occasional rough idle or stalling may be noticed, especially during warm weather. The rough idle and stalling may also be noticeable after the engine is started, driven, then stopped for a short time. Engine heat can vaporize the alcoholenhanced fuel causing bubbles to form in the fuel system. These bubbles in the fuel prevent the proper operation of the fuel injection system and result in a hesitation during acceleration, rough idle, or in severe cases repeated stalling until all the bubbles have been forced through the fuel system, replaced by cooler fuel from the fuel tank.
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FREQUENTLY ASKED QUESTION
What Is “Top-Tier” Gasoline? Top-tier gasoline is gasoline that has specific standards for quality, including enough detergent to keep all intake valves clean. Four automobile manufacturers, including BMW, General Motors, Honda, and Toyota, developed the standards. Top-tier gasoline exceeds the quality standards developed by the World Wide Fuel Charter (WWFC) that was established in 2002 by vehicle and engine manufacturers. The gasoline companies that agreed to make fuel that matches or exceeds the standards as a top-tier fuel include Shell, ChevronTexaco and ConocoPhillips. Ford has specified that BP fuel, sold in many parts of the country, is the recommended fuel to use in Ford vehicles. SEE FIGURE 66–16.
FREQUENTLY ASKED QUESTION
Why Should I Keep the Fuel Gauge Above One-Quarter Tank? The fuel pickup inside the fuel tank can help keep water from being drawn into the fuel system unless water is all that is left at the bottom of the tank. Over time, moisture in the air inside the fuel tank can condense, causing liquid water to drop to the bottom of the fuel tank (water is heavier than gasoline–about 8 lb per gallon for water and about 6 lb per gallon for gasoline). If alcohol-blended gasoline is used, the alcohol can absorb the water and the alcohol–water combination can be burned inside the engine. However, when water combines with alcohol, a separation layer occurs between the gasoline at the top of the tank and the alcohol–water combination at the bottom. When the fuel level is low, the fuel pump will draw from this concentrated level of alcohol and water. Because alcohol and water do not burn as well as pure gasoline, severe driveability problems can occur such as stalling, rough idle, hard starting, and missing.
GENERAL GASOLINE RECOMMENDATIONS The fuel used by an engine is a major expense in the operation cost of the vehicle. The proper operation of the engine depends on clean fuel of the proper octane rating and vapor pressure for the atmospheric conditions. To help ensure proper engine operation and keep fuel costs to a minimum, follow these guidelines: 1. Purchase fuel from a busy station to help ensure that it is fresh and less likely to be contaminated with water or moisture. 2. Keep the fuel tank above one-quarter full, especially during seasons in which the temperature rises and falls by more than 20°F between daytime highs and nighttime lows. This helps to reduce condensed moisture in the fuel tank and could prevent gas line freeze-up in cold weather.
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TECH TIP Do Not Overfill the Fuel Tank Gasoline fuel tanks have an expansion volume area at the top. The volume of this expansion area is equal to 10% to 15% of the volume of the tank. This area is normally not filled with gasoline, but rather is designed to provide a place for the gasoline to expand into, if the vehicle is parked in the hot sun and the gasoline expands. This prevents raw gasoline from escaping from the fuel system. A small restriction is usually present to control the amount of air and vapors that can escape the tank and flow to the charcoal canister. This volume area could be filled with gasoline if the fuel is slowly pumped into the tank. Since it can hold an extra 10% (2 gallons in a 20-gallon tank), some people deliberately try to fill the tank completely. When this expansion volume is filled, liquid fuel (rather than vapors) can be drawn into the charcoal canister. When the purge valve opens, liquid fuel can be drawn into the engine, causing an excessively rich air-fuel mixture. Not only can this liquid fuel harm vapor recovery parts, but overfilling the gas tank could also cause the vehicle to fail an exhaust emission test, particularly during an enhanced test when the tank could be purged while on the rollers.
NOTE: Gas line freeze-up occurs when the water in the gasoline freezes and forms an ice blockage in the fuel line. 3. Do not purchase fuel with a higher octane rating than is necessary. Most newer engines are equipped with a detonation (knock) sensor that signals the vehicle computer to retard the ignition timing when spark knock occurs. Therefore, an operating difference may not be noticeable to the driver when using a low-octane fuel, except for a decrease in power and fuel economy. In other words, the engine with a knock sensor will tend to operate knock free on regular fuel, even if premium, higher-octane fuel is specified. Using premium fuel may result in more power and greater fuel economy. The increase in fuel economy, however, would have to be substantial to justify the increased cost of high-octane premium fuel. Some drivers find a good compromise by using midgrade (plus) fuel to benefit from the engine power and fuel economy gains without the cost of using premium fuel all the time. 4. Avoid using gasoline with alcohol in warm weather, even though many alcohol blends do not affect engine driveability. If warm-engine stumble, stalling, or rough idle occurs, change brands of gasoline. 5. Do not purchase fuel from a retail outlet when a tanker truck is filling the underground tanks. During the refilling procedure, dirt, rust, and water may be stirred up in the underground tanks. This undesirable material may be pumped into your vehicle’s fuel tank. 6. Do not overfill the gas tank. After the nozzle clicks off, add just enough fuel to round up to the next dime. Adding additional gasoline will cause the excess to be drawn into the charcoal canister. This can lead to engine flooding and excessive exhaust emissions. 7. Be careful when filling gasoline containers. Always fill a gas can on the ground to help prevent the possibility of static electricity buildup during the refueling process. SEE FIGURE 66–17.
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FIGURE 66–17 Many gasoline service stations have signs posted warning customers to place plastic fuel containers on the ground while filling. If placed in a trunk or pickup truck bed equipped with a plastic liner, static electricity could build up during fueling and discharge from the container to the metal nozzle, creating a spark and possible explosion. Some service stations have warning signs not to use cell phones while fueling to help avoid the possibility of an accidental spark creating a fire hazard.
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FREQUENTLY ASKED QUESTION
What Are the Pump Nozzle Sizes? Unleaded gasoline nozzles are smaller than those used for diesel fuel to help prevent fueling errors. However, it is still possible to fuel a diesel vehicle with gasoline. SEE CHART 66–1 for the sizes and colors used for fuel pump nozzles.
Fuel
Nozzle Diameter
Pump Handle Color (Varies—no established standard)
Gasoline
13/16 in. (21 mm)
Black, red, white, green, or blue
E10
13/16 in. (21 mm)
Black, red, white, green, or blue
E85
13/16 in. (21 mm)
Yellow or black
Diesel fuel
15/16 in. (24 mm)
Yellow, green, or black
Biodiesel
15/16 in. (24 mm)
Green
Truckstop diesel
1 1/14 or 1 1/2 in. (32 or 38 mm)
Varies
CHART 66–1 Fuel pump nozzle size is standardized except for use by overthe-road truck stops where high fuel volumes and speedy refills require larger nozzle sizes compared to passenger vehicle filling station nozzles.
TESTING FOR ALCOHOL CONTENT IN GASOLINE
1
A fuel composition tester (SPX Kent-Moore J-44175) is the recommended tool, by General Motors, to use to test the alcohol content of gasoline.
2
This battery-powered tester uses light-emitting diodes (LEDs), meter lead terminals, and two small openings for the fuel sample.
3
The first step is to verify the proper operation of the tester by measuring the air frequency by selecting AC hertz on the meter. The air frequency should be between 35 and 48 Hz.
4
After verifying that the tester is capable of correctly reading the air frequency, gasoline is poured into the testing cell of the tool.
6
Adding additional amounts of ethyl alcohol (ethanol) increases the frequency reading.
5
Record the AC frequency as shown on the meter and subtract 50 from the reading. (e.g., 60.50 50.00 10.5). This number (10.5) is the percentage of alcohol in the gasoline sample.
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REVIEW QUESTIONS 1. What is the difference between summer-blend and winterblend gasoline?
4. What does the (R M) 2 gasoline pump octane rating indicate?
2. What is Reid vapor pressure?
5. What are the octane improvers that may be used during the refining process?
3. What is vapor lock?
6. What is stoichiometric?
CHAPTER QUIZ 1. Winter-blend gasoline ______________. a. Vaporizes more easily than summer-blend gasoline b. Has a higher RVP c. Can cause engine driveability problems if used during warm weather d. All of the above
6. Which method of blending ethanol with gasoline is the most accurate? a. In-line b. Sequential c. Splash d. All of the above are equally accurate methods
2. Vapor lock can occur ______________. a. As a result of excessive heat near fuel lines b. If a fuel line is restricted c. During both a and b d. During neither a nor b
7. What can be used to measure the alcohol content in gasoline? a. Graduated cylinder c. Scan tool b. Electronic tester d. Either a or b
3. Technician A says that spark knock, ping, and detonation are different names for abnormal combustion. Technician B says that any abnormal combustion raises the temperature and pressure inside the combustion chamber and can cause severe engine damage. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 4. Technician A says that the research octane number is higher than the motor octane number. Technician B says that the octane rating posted on fuel pumps is an average of the two ratings. Which technician is correct? a. Technician A only c. Both Technicians A and B b. Technician B only d. Neither Technician A nor B 5. Technician A says that in going to high altitudes, engines produce lower power. Technician B says that most engine control systems can compensate the air-fuel mixture for changes in altitude. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
chapter
8. To avoid problems with the variation of gasoline, all government testing uses ______________ as a fuel during testing procedures. a. MTBE (methyl tertiary butyl ether) b. Indolene c. Xylene d. TBA (tertiary butyl alcohol) 9. Avoid topping off the fuel tank because ______________. a. It can saturate the charcoal canister b. The extra fuel simply spills onto the ground c. The extra fuel increases vehicle weight and reduces performance d. The extra fuel goes into the expansion area of the tank and is not used by the engine 10. Using ethanol-enhanced or reformulated gasoline can result in reduced fuel economy. a. True b. False
ALTERNATIVE FUELS
67 OBJECTIVES: After studying Chapter 67, the reader should be able to: • Describe how alternative fuels affect engine performance. • List alternatives to gasoline. • Discuss how alternative fuels affect driveability. • Explain how alternative fuels can reduce CO exhaust emissions. • Discuss safety precautions when working with alternative fuels.
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KEY TERMS: AFV 768 • Anhydrous ethanol 767 • Biomass 772 • Cellulose ethanol 767 • Cellulosic biomass 767 • Coal to liquid (CTL) 775 • Compressed natural gas (CNG) 772 • E85 768 • Ethanol 767 • Ethyl alcohol 767 • FFV 768 • Fischer-Tropsch 775 • Flex fuels 768 • FTD 775 • Fuel compensation sensor 768 • Gas to liquid (GTL) 775 • Grain alcohol 767 • Liquid petroleum gas (LPG) 772 • LP-gas 772 • M85 772 • Methanol 771 • Methanol to gasoline (MTG) 776 • NGV 772 • Propane 772 • Switchgrass 768 • Syncrude 776 • Syn-gas 772 • Synthetic fuel 774 • Underground coal gasification (UCG) 776 • V-FFV 771 • Variable fuel sensor 768
ETHANOL H
ETHANOL TERMINOLOGY
Ethanol is also called ethyl alcohol or grain alcohol, because it is usually made from grain and is the type of alcohol found in alcoholic drinks such as beer, wine, and distilled spirits like whiskey. Ethanol is composed of two carbon atoms and six hydrogen atoms with one added oxygen atom. SEE FIGURE 67–1.
ETHANOL PRODUCTION
Conventional ethanol is derived from grains, such as corn, wheat, or soybeans. Corn, for example, is converted to ethanol in either a dry or wet milling process. In dry milling operations, liquefied cornstarch is produced by heating cornmeal with water and enzymes. A second enzyme converts the liquefied starch to sugars, which are fermented by yeast into ethanol and carbon dioxide. Wet milling operations separate the fiber, germ (oil), and protein from the starch before it is fermented into ethanol. The majority of the ethanol in the United States is made from:
Corn
Grain
Sorghum
Wheat
Barley
Potatoes
In Brazil, the world’s largest ethanol producer, it is made from sugarcane. Ethanol can be made by the dry mill process in which the starch portion of the corn is fermented into sugar and then distilled into alcohol. The major steps in the dry mill process include: 1. Milling. The feedstock passes through a hammer mill that turns it into a fine powder called meal. 2. Liquefaction. The meal is mixed with water and then passed through cookers where the starch is liquefied. Heat is applied at this stage to enable liquefaction. Cookers use a high-temperature stage of about 250°F to 300°F (120°C to 150°C) to reduce bacteria levels and then a lower temperature of about 200°F (95°C) for a holding period. 3. Saccharification. The mash from the cookers is cooled and a secondary enzyme is added to convert the liquefied starch to fermentable sugars (dextrose). 4. Fermentation. Yeast is added to the mash to ferment the sugars to ethanol and carbon dioxide. 5. Distillation. The fermented mash, now called beer, contains about 10% alcohol plus all the nonfermentable solids from the corn and yeast cells. The mash is pumped to the continuousflow, distillation system where the alcohol is removed from the solids and the water. The alcohol leaves the top of the final column at about 96% strength, and the residue mash, called silage, is transferred from the base of the column to the co-product processing area.
O
H
H
C
C
H
H
H
FIGURE 67–1 The ethanol molecule showing two carbon atoms, six hydrogen atoms, and one oxygen atom.
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FREQUENTLY ASKED QUESTION
Does Ethanol Production Harm the Environment? The production of ethanol is referred to as being carbon neutral because the amount of CO2 released during production is equal to the amount of CO2 that would be released if the corn or other products were left to decay.
6. Dehydration. The alcohol from the top of the column passes through a dehydration system where the remaining water will be removed. The alcohol product at this stage is called anhydrous ethanol (pure, no more than 0.5% water). 7. Denaturing. Ethanol that will be used for fuel must be denatured, or made unfit for human consumption, with a small amount of gasoline (2% to 5%), methanol, or denatonium benzoate. This is done at the ethanol plant.
CELLULOSE ETHANOL TERMINOLOGY Cellulose ethanol can be produced from a wide variety of cellulose biomass feedstock, including:
Agricultural plant wastes (corn stalks, cereal straws)
Plant wastes from industrial processes (sawdust, paper pulp)
Energy crops grown specifically for fuel production.
These nongrain products are often referred to as cellulosic biomass. Cellulosic biomass is composed of cellulose and lignin, with smaller amounts of proteins, lipids (fats, waxes, and oils), and ash. About two-thirds of cellulosic materials are present as cellulose, with lignin making up the bulk of the remaining dry mass.
REFINING CELLULOSE BIOMASS As with grains, processing cellulose biomass involves extracting fermentable sugars from the feedstock. But the sugars in cellulose are locked in complex carbohydrates called polysaccharides (long chains of simple sugars). Separating these complex structures into fermentable sugars
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FREQUENTLY ASKED QUESTION
What Is Switchgrass? Switchgrass (Panicum virgatum) can be used to make ethanol and is a summer perennial grass that is native to North America. It is a natural component of the tall-grass prairie, which covered most of the Great Plains, but was also found on the prairie soils in the Black Belt of Alabama and Mississippi. Switchgrass is resistant to many pests and plant diseases, and is capable of producing high yields with very low applications of fertilizer. This means that the need for agricultural chemicals to grow switchgrass is relatively low. Switchgrass is also very tolerant of poor soils, flooding, and drought, which are widespread agricultural problems in the Southeast. There are two main types of switchgrass: • Upland types—usually grow 5 to 6 feet tall • Lowland types—grow up to 12 feet tall and are typically found on heavy soils in bottomland sites Better energy efficiency is gained because less energy is used to produce ethanol from switchgrass.
is needed to achieve the efficient and economic production of cellulose ethanol. Two processing options are employed to produce fermentable sugars from cellulose biomass:
Acid hydrolysis is used to break down the complex carbohydrates into simple sugars.
Enzymes are employed to convert the cellulose biomass to fermentable sugars. The final step involves microbial fermentation, yielding ethanol and carbon dioxide.
NOTE: Cellulose ethanol production substitutes biomass for fossil fuels. The greenhouse gases produced by the combustion of biomass are offset by the CO2 absorbed by the biomass as it grows in the field.
E85 WHAT IS E85? Vehicle manufacturers have available vehicles that are capable of operating on gasoline plus ethanol or a combination of gasoline and ethanol called E85. E85 is composed of 85% ethanol and 15% gasoline. Pure ethanol has an octane rating of about 113. E85, which contains 35% oxygen by weight, has an octane rating of about 100 to 105. This compares to a regular unleaded gasoline, which has a rating of 87. SEE FIGURE 67–2. NOTE: The octane rating of E85 depends on the exact percent of ethanol used, which can vary from 81% to 85%. It also depends on the octane rating of the gasoline used to make E85.
HEAT ENERGY OF E85
E85 has less heat energy than gasoline.
Gasoline 114,000 BTUs per gallon E85 87,000 BTUs per gallon
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FIGURE 67–2 Some retail stations offer a variety of fuel choices, such as this station in Ohio where E10 and E85 are available.
This means that the fuel economy is reduced by 20% to 30% if E85 is used instead of gasoline. Example: A Chevrolet Tahoe 5.3-liter V-8 with an automatic transmission has an EPA rating of 15 mpg in the city and 20 mpg on the highway when using gasoline. If this same vehicle was fueled with E85, the EPA fuel economy rating drops to 11 mpg in the city and 15 mpg on the highway.
ALTERNATIVE-FUEL VEHICLES The 15% gasoline in this blend helps the engine start, especially in cold weather. Vehicles equipped with this capability are commonly referred to as alternative-fuel vehicles (AFVs), flex fuels, and flexible fuel vehicles, or FFVs. Using E85 in a flex-fuel vehicle can result in a power increase of about 5%. For example, an engine rated at 200 hp using gasoline or E10 could produce 210 hp if using E85. NOTE: E85 may test as containing less than 85% ethanol if tested in cold climates because it is often blended according to outside temperature. A lower percentage of ethanol with a slightly higher percentage of gasoline helps engines start in cold climates. These vehicles are equipped with an electronic sensor in the fuel supply line that detects the presence and percentage of ethanol. The PCM then adjusts the fuel injector on-time and ignition timing to match the needs of the fuel being used. E85 contains less heat energy, and therefore will use more fuel, but the benefits include a lower cost of the fuel and the environmental benefit associated with using an oxygenated fuel. General Motors, Ford, Chrysler, Mazda, and Honda are a few of the manufacturers offering E85 compatible vehicles. E85 vehicles use fuel system parts designed to withstand the additional alcohol content, modified driveability programs that adjust fuel delivery and timing to compensate for the various percentages of ethanol fuel, and a fuel compensation sensor that measures both the percentage of ethanol blend and the temperature of the fuel. This sensor is also called a variable fuel sensor. SEE FIGURES 67–3 AND 67–4.
VARIABLE FUEL SENSOR
BRAKE FLUID RESERVOIR
FIGURE 67–3 The location of the variable fuel sensor can vary, depending on the make and model of vehicle, but it is always in the fuel line between the fuel tank and the fuel injectors.
FIGURE 67–5 A pump for E85 (85% ethanol and 15% gasoline). E85 is available in more locations every year.
TECH TIP
ELECTRICAL HARNESS AND CONNECTOR
Purchase a Flex-Fuel Vehicle
UPPER HOUSING LOWER HOUSING
If purchasing a new or used vehicle, try to find a flex-fuel vehicle. Even though you may not want to use E85, a flex-fuel vehicle has a more robust fuel system than a conventional fuel system designed for gasoline or E10. The enhanced fuel system components and materials usually include:
FUEL OUT
FUEL IN CIRCUIT BOARD
• Stainless steel fuel rail • Graphite commutator bars instead of copper in the fuel pump motor (ethanol can oxidize into acetic acid, which can corrode copper) • Diamond-like carbon (DLC) corrosion-resistant fuel injectors • Alcohol-resistant O-rings and hoses
OUTER TUBE (NEGATIVE PLATE) INNER TUBE (POSITIVE PLATE)
FIGURE 67–4 A cutaway view of a typical variable fuel sensor.
E85 FUEL SYSTEM REQUIREMENTS Most E85 vehicles are very similar to non-E85 vehicles. Fuel system components may be redesigned to withstand the effects of higher concentrations of ethanol. In addition, since the stoichiometric point for ethanol is 9:1 instead of 14.7:1 as for gasoline, the air-fuel mixture has to be adjusted for the percentage of ethanol present in the fuel tank. In order to determine this percentage of ethanol in the fuel tank, a compensation sensor is used. The fuel compensation sensor is the only additional piece of hardware required on some E85 vehicles. The fuel compensation sensor provides both the ethanol percentage and the fuel temperature to the PCM. The PCM uses this information to adjust both the ignition timing and the quantity of fuel delivered to the engine. The fuel compensation sensor uses a microprocessor to measure both the ethanol percentage and the fuel temperature. This information is sent to the PCM on the signal circuit. The compensation sensor produces a square wave frequency and pulse width signal. The normal frequency range of the fuel compensation sensor is 50 hertz, which represents 0% ethanol and 150 hertz, which represents 100% ethanol. The pulse width of the signal varies from 1 millisecond to 5 milliseconds. One millisecond would represent a fuel temperature of 40°F (40°C), and 5 milliseconds would represent a fuel temperature of 257°F (125°C). Since the PCM knows both the fuel temperature and the ethanol percentage of the fuel, it
The cost of a flex-fuel vehicle compared with the same vehicle designed to operate on gasoline is a no-cost or a low-cost option.
can adjust fuel quantity and ignition timing for optimum performance and emissions. The benefits of E85 vehicles are less pollution, less CO2 production, and less dependence on oil. SEE FIGURE 67–5. Ethanol-fueled vehicles generally produce the same pollutants as gasoline vehicles; however, they produce less CO and CO2 emissions. While CO2 is not considered a pollutant, it is thought to lead to global warming and is called a greenhouse gas.
FLEX-FUEL VEHICLE IDENTIFICATION
Flexible fuel vehi-
cles (FFVs) can be identified by:
Emblems on the side, front, and/or rear of the vehicle
Yellow fuel cap showing E85/gasoline ( SEE FIGURE 67–6)
Vehicle emission control information (VECI) label under the hood ( SEE FIGURE 67–7)
Vehicle identification number (VIN)
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FIGURE 67–6 A flex-fuel vehicle often has a yellow gas cap, which is labeled E85/gasoline.
Vehicles that are flexible fuel include:
FIGURE 67–7 A vehicle emission control information (VECI) sticker on a flexible fuel vehicle indicating that it can use ethanol from 0 to 85%.
General Motors *Select vehicles only—see your owner’s manual.
Chrysler 2004 • 4.7L Dodge Ram Pickup 1500 Series • 2.7L Dodge Stratus Sedan • 2.7L Chrysler Sebring Sedan • 3.3L Caravan and Grand Caravan SE 2003–2004 • 2.7L Dodge Stratus Sedan • 2.7L Chrysler Sebring Sedan 2003 • 3.3L Dodge Cargo Minivan
2005 • 5.3L Vortec-Engine Avalanche • 5.3L Vortec-Engine Police Package Tahoe 2003–2005 • 5.3L V8 Chevy Silverado* and GMC Sierra* Half-Ton Pickups 2WD and 4WD • 5.3L Vortec-Engine Suburban, Tahoe, Yukon, and Yukon XL 2002 • 5.3L V8 Chevy Silverado* and GMC Sierra* Half-Ton Pickups 2WD and 4WD • 5.3L Vortec-Engine Suburban, Tahoe, Yukon, and Yukon XL
2000–2003 • 3.3L Chrysler Voyager Minivan
• 2.2L Chevy S10 Pickup 2WD
• 3.3L Dodge Caravan Minivan 3.3L Chrysler Town and Country Minivan
2000–2001 • 2.2L Chevy S10 Pickup 2WD
1998–1999 • 3.3L Dodge Caravan Minivan
• 2.2L GMC Sonoma Pickup 2WD
• 3.3L Plymouth Voyager Minivan • 3.3L Chrysler Town & Country Minivan
2000–2001 • 2.2L Hombre Pickup 2WD
Ford Motor Company
Mazda
*Ford offers the flex fuel capability as an option on select vehicles—see the owner’s manual.
1999–2003 • 3.0L Selected B3000 Pickups
2004 • 4.0L Explorer Sport Trac
Mercedes-Benz
• 4.0L Explorer (4-door) • 3.0L Taurus Sedan and Wagon 2002–2004 • 4.0L Explorer (4-door) • 3.0L Taurus Sedan and Wagon 2002–2003 • 3.0L Supercab Ranger Pickup 2WD 2001 • 3.0L Supercab Ranger Pickup 2WD • 3.0L Taurus LX, SE, and SES Sedan 1999–2000 • 3.0L Ranger Pickup 4WD and 2WD
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• 2.2L Sonoma GMC Pickup 2WD
Isuzu
2005 • 2.6L C240 Luxury Sedan and Wagon 2003 • 3.2L C320 Sport Sedan and Wagon Mercury 2002–2004 • 4.0L Selected Mountaineers 2000–2004 • 3.0L Selected Sables Nissan 2005 • 5.6L DOHC V8 Engine *Select vehicles only—see the owner’s manual or VECI sticker under the hood.
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TECH TIP
FREQUENTLY ASKED QUESTION
How Does a Sensorless Flex-Fuel System Work?
Avoid Resetting Fuel Compensation
Many General Motors flex-fuel vehicles do not use a fuel compensation sensor and instead use the oxygen sensor to detect the presence of the lean mixture and the extra oxygen in the fuel. The powertrain control module (PCM) then adjusts the injector pulse-width and the ignition timing to optimize engine operation to the use of E85. This type of vehicle is called a virtual flexible fuel vehicle, abbreviated V-FFV. The virtual flexible fuel vehicle can operate on pure gasoline or blends up to 85% ethanol.
Starting in 2006, General Motors vehicles designed to operate on E85 do not use a fuel compensation sensor, but instead use the oxygen sensor and refueling information to calculate the percentage of ethanol in the fuel. The PCM uses the fuel level sensor to sense that fuel has been added and starts to determine the resulting ethanol content by using the oxygen sensor. However, if a service technician were to reset fuel compensation by clearing long-term fuel trim, the PCM starts the calculation based on base fuel, which is gasoline with less than or equal to 10% ethanol (E10). If the fuel tank has E85, then the fuel compensation cannot be determined unless the tank is drained and refilled with base fuel. Therefore, avoid resetting the fuel compensation setting unless it is known that the fuel tank contains gasoline or E10 only.
HOW TO READ A VEHICLE IDENTIFICATION NUMBER The vehicle identification number (VIN) is required by federal regulation to contain specific information about the vehicle. The following chart shows the character in the eighth position of the VIN number from Ford Motor Company, General Motors, and Chrysler that designates their vehicles as flexible fuel vehicles. Ford Motor Company Vehicle
8th Character
Ford Crown Victoria
V
Ford F-150
V
Ford Explorer
K
Ford Ranger
V
Ford Taurus
2
Lincoln Town Car
V
Mercury Mountaineer
K
Mercury Sable
2
Mercury Grand Marquis
V General Motors
Vehicle
8th Character
Chevrolet Avalanche
Z
Chevrolet Impala
K
Chevrolet Monte Carlo
K
Chevrolet S-10 Pickup
5
Chevrolet Sierra
Z
Chevrolet Suburban
Z
Chevrolet Tahoe
Z
GMC Yukon and Yukon XL
Z
GMC Silverado
Z
GMC Sonoma
5
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FREQUENTLY ASKED QUESTION
How Long Can Oxygenated Fuel Be Stored Before All of the Oxygen Escapes? The oxygen in oxygenated fuels, such as E10 and E85, is not in a gaseous state like the CO2 in soft drinks. The oxygen is part of the molecule of ethanol or other oxygenates and does not bubble out of the fuel. Oxygenated fuels, just like any fuel, have a shelf life of about 90 days.
Mazda Vehicle
8th Character
B3000 Pickup
V
Nissan Vehicle
4th Character
Titan
B
Mercedes Benz Check owner’s manual or the VECI sticker under the hood.
NOTE: For additional information on E85 and for the location of E85 stations in your area, go to www.e85fuel.com.
Chrysler Vehicle
8th Character
Chrysler Sebring
T
Chrysler Town & Country
E, G or 3
Dodge Caravan
E, G or 3
Dodge Cargo Minivan
E, G or 3
Dodge Durango
P
Dodge Ram
P
Dodge Stratus
T
Plymouth Voyageur
E, G or 3
METHANOL METHANOL TERMINOLOGY
Methanol, also known as methyl alcohol, wood alcohol, or methyl hydrate, is a chemical compound formula that includes one carbon atom and four hydrogen atoms and one oxygen. SEE FIGURE 67–8. Methanol is a light, volatile, colorless, tasteless, flammable, poisonous liquid with a very faint odor. It is used as an antifreeze, a solvent, and a fuel. Methanol burns in air, forming CO2 (carbon dioxide)
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H
H
O
C
H
H
FIGURE 67–8 The molecular structure of methanol showing the one carbon atom, four hydrogen atoms, and one oxygen atom.
FIGURE 67–10 Propane fuel storage tank in the trunk of a Ford taxi.
to fumes or handles liquid without skin protection. If methanol has been ingested, a doctor should be contacted immediately. The usual fatal dose is 4 fl oz (100 to 125 mL).
M85
FIGURE 67–9 Sign on methanol pump shows that methyl alcohol is a poison and can cause skin irritation and other personal injury. Methanol is used in industry as well as being a fuel. and H2O (water). A methanol flame is almost colorless. Because of its poisonous properties, methanol is also used to denature ethanol. Methanol is often called wood alcohol because it was once produced chiefly as a by-product of the destructive distillation of wood. SEE FIGURE 67–9.
PRODUCTION OF METHANOL The biggest source of methanol in the United States is coal. Using a simple reaction between coal and steam, a gas mixture called syn-gas (synthesis gas) is formed. The components of this mixture are carbon monoxide and hydrogen, which, through an additional chemical reaction, are converted to methanol. Natural gas can also be used to create methanol and is reformed or converted to synthesis gas, which is later made into methanol. Biomass can be converted to synthesis gas by a process called partial oxidation, and later converted to methanol. Biomass is organic material, such as:
Urban wood wastes
Primary mill residues
Forest residues
Agricultural residues
Dedicated energy crops (e.g., sugarcane and sugar beets) that can be made into fuel
Electricity can be used to convert water into hydrogen, which is then reacted with carbon dioxide to produce methanol. Methanol is toxic and can cause blindness and death. It can enter the body by ingestion, inhalation, or absorption through the skin. Dangerous doses will build up if a person is regularly exposed
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Some flexible fuel vehicles are designed to operate on 85% methanol and 15% gasoline called M85. Methanol is very corrosive and requires that the fuel system components be constructed of stainless steel and other alcohol-resistant rubber and plastic components. The heat content of M85 is about 60% of that of gasoline.
PROPANE Propane is the most widely used of all of the alternative fuels. Propane is normally a gas but is easily compressed into a liquid and stored in inexpensive containers. When sold as a fuel, it is also known as liquefied petroleum gas (LPG) or LP-gas because the propane is often mixed with about 10% of other gases such as butane, propylene, butylenes, and mercaptan to give the colorless and odorless propane a smell. Propane is nontoxic, but if inhaled can cause asphyxiation through lack of oxygen. Propane is heavier than air and lays near the floor if released into the atmosphere. Propane is commonly used in forklifts and other equipment used inside warehouses and factories because the exhaust from the engine using propane is not harmful. Propane is a by-product of petroleum refining of natural gas. In order to liquefy the fuel, it is stored in strong tanks at about 300 PSI (2,000 kPa). The heating value of propane is less than that of gasoline; therefore, more is required, which reduces the fuel economy. SEE FIGURE 67–10.
COMPRESSED NATURAL GAS CNG VEHICLE DESIGN
Another alternative fuel that is often used in fleet vehicles is compressed natural gas, or CNG, and vehicles using this fuel are often referred to as natural gas vehicles (NGVs). Look for the blue CNG label on vehicles designed to operate on compressed natural gas. SEE FIGURE 67–11. Natural gas has to be compressed to about 3,000 PSI (20,000 kPa) or more, so that the weight and the cost of the
FIGURE 67–11 The blue sticker on the rear of this vehicle indicates that it is designed to use compressed natural gas. FIGURE 67–13 The fuel injectors used on this Honda Civic GX CNG engine are designed to flow gaseous fuel instead of liquid fuel and cannot be interchanged with any other type of injector.
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FREQUENTLY ASKED QUESTION
What Is the Amount of CNG Equal to in Gasoline? To achieve the amount of energy of one gallon of gasoline, 122 cubic feet of compressed natural gas (CNG) is needed. While the octane rating of CNG is much higher than gasoline (130 octane), using CNG instead of gasoline in the same engine would result in a reduction of 10% to 20% of power due to the lower heat energy that is released when CNG is burned in the engine. FIGURE 67–12 A CNG storage tank from a Honda Civic GX shown with the fixture used to support it while it is being removed or installed in the vehicle. Honda specifies that three technicians be used to remove or install the tank through the rear door of the vehicle due to the size and weight of the tank. storage container is a major factor when it comes to preparing a vehicle to run on CNG. The tanks needed for CNG are typically constructed of 0.5-inch-thick (3 mm) aluminum reinforced with fiberglass. SEE FIGURE 67–12. The octane rating of CNG is about 130 and the cost per gallon is about half of the cost of gasoline. However, the heat value of CNG is also less, and therefore more is required to produce the same power and the miles per gallon is less.
CNG COMPOSITION
Compressed natural gas is made up of
a blend of:
Methane
Propane
Ethane
N-butane
Carbon dioxide
Nitrogen
Once it is processed, it is at least 93% methane. Natural gas is nontoxic, odorless, and colorless in its natural state. It is odorized during processing, using ethyl mercaptan ( “skunk”), to allow for easy leak detection. Natural gas is lighter than air and will rise when released into the air. Since CNG is already a vapor, it does not need heat to vaporize before it will burn, which improves cold start-up and
results in lower emissions during cold operation. However, because it is already in a gaseous state, it does displace some of the air charge in the intake manifold. This leads to about a 10% reduction in engine power as compared to an engine operating on gasoline. Natural gas also burns slower than gasoline; therefore, the ignition timing must be advanced more when the vehicle operates on natural gas. The stoichiometric ratio, the point at which all the air and fuel is used or burned is 16.5:1 compared to 14.7:1 for gasoline. This means that more air is required to burn one pound of natural gas than is required to burn one pound of gasoline. SEE FIGURE 67–13. The CNG engine is designed to include:
Increased compression ratio
Strong pistons and connecting rods
Heat-resistant valves
Fuel injectors designed for gaseous fuel instead of liquid fuel
CNG FUEL SYSTEMS When completely filled, the CNG tank has 3,600 PSI of pressure in the tank. When the ignition is turned on, the alternate fuel electronic control unit activates the highpressure lock-off, which allows high-pressure gas to pass to the high-pressure regulator. The high-pressure regulator reduces the high-pressure CNG to approximately 170 PSI and sends it to the low-pressure lock-off. The low-pressure lock-off is also controlled by the alternate fuel electronic control unit and is activated at the same time that the high-pressure lock-off is activated. From the low-pressure lock-off, the CNG is directed to the low-pressure regulator. This is a two-stage regulator that first reduces the pressure to approximately 4 to 6 PSI in the first stage and then to 4.5 to 7 inches
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COMPOSITION OF P-SERIES FUELS (BY VOLUME) COMPONENT
REGULAR GRADE
PREMIUM GRADE
COLD WEATHER
Pentanes plus
32.5%
27.5%
16.0%
MTHF
32.5%
17.5%
26.0%
Ethanol
35.0%
55.0%
47.0%
Butane
0.0%
0.0%
11.0%
CHART 67–1 P-series fuel varies in composition, depending on the octane rating and temperature.
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FIGURE 67–14 This CNG pump is capable of supplying compressed natural gas at either 3,000 PSI or 3,600 PSI. The price per gallon is higher for the higher pressure. of water in the second stage. Twenty-eight inches of water is equal to 1 PSI, therefore, the final pressure of the natural gas entering the engine is very low. From here, the low-pressure gas is delivered to the gas mass sensor/mixture control valve. This valve controls the air-fuel mixture. The CNG gas distributor adapter then delivers the gas to the intake stream. CNG vehicles are designed for fleet use that usually have their own refueling capabilities. One of the drawbacks to using CNG is the time that it takes to refuel a vehicle. The ideal method of refueling is the slow fill method. The slow filling method compresses the natural gas as the tank is being fueled. This method ensures that the tank will receive a full charge of CNG; however, this method can take three to five hours to accomplish. If more than one vehicle needs filling, the facility will need multiple CNG compressors to refuel the vehicles. There are three commonly used CNG refilling station pressures: P24—2,400 PSI P30—3,000 PSI P36—3,600 PSI Try to find and use a station with the highest refilling pressure. Filling at lower pressures will result in less compressed natural gas being installed in the storage tank, thereby reducing the driving range. SEE FIGURE 67–14. The fast fill method uses CNG that is already compressed. However, as the CNG tank is filled rapidly, the internal temperature of the tank will rise, which causes a rise in tank pressure. Once the temperature drops in the CNG tank, the pressure in the tank also drops, resulting in an incomplete charge in the CNG tank. This refueling method may take only about five minutes; however, it will result in an incomplete charge to the CNG tank, reducing the driving range.
LIQUEFIED NATURAL GAS Natural gas can be turned into a liquid if cooled to below 260°F (127°C). The natural gas condenses into a liquid at normal atmospheric pressure and the volume is reduced by about 600 times. This means that the natural gas can be more efficiently transported over long distances where no pipelines are present when liquefied. Because the temperature of liquefied natural gas (LNG) must be kept low, it is only practical for use in short haul trucks where they can be refueled from a central location.
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FREQUENTLY ASKED QUESTION
What Is a Tri-Fuel Vehicle? In Brazil, most vehicles are designed to operate on ethanol or gasoline or any combination of the two. In this South American country, ethanol is made from sugarcane, is commonly available, and is lower in price than gasoline. Compressed natural gas (CNG) is also being made available so many vehicle manufacturers in Brazil, such as General Motors and Ford, are equipping vehicles to be capable of using gasoline, ethanol, or CNG. These vehicles are called tri-fuel vehicles.
P-SERIES FUELS P-series alternative fuel is patented by Princeton University and is a non-petroleum- or natural gas-based fuel suitable for use in flexible fuel vehicles or any vehicle designed to operate on E85 (85% ethanol, 15% gasoline). P-series fuel is recognized by the United States Department of Energy as being an alternative fuel, but is not yet available to the public. P-series fuels are blends of the following:
Ethanol (ethyl alcohol)
Methyltetrahydrofuron, abbreviated MTHF
Natural gas liquids, such as pentanes
Butane
The ethanol and MTHF are produced from renewable feedstocks, such as corn, waste paper, biomass, agricultural waste, and wood waste (scraps and sawdust). The components used in P-type fuel can be varied to produce regular grade, premium grade, or fuel suitable for cold climates. SEE CHART 67–1 for the percentages of the ingredients based on fuel grade. SEE CHART 67–2 for a comparison of the most frequently used alternative fuels.
SYNTHETIC FUELS Synthetic fuels can be made from a variety of products, using several different processes. Synthetic fuel must, however, make these alternatives practical only when conventional petroleum products are either very expensive or not available.
ALTERNATIVE FUEL COMPARISON CHART CHARACTERISTIC
PROPANE
CNG
METHANOL
ETHANOL
REGULAR UNLEADED GAS
Octane
104
130
100
100
87–93
BTU per gallon
91,000
N.A.
70,000
83,000
114,000–125,000
Gallon equivalent
1.15
122 cubic feet— 1 gallon of gasoline
1.8
1.5
1
On-board fuel storage
Liquid
Gas
Liquid
Liquid
Liquid
Miles/gallon as compared to gas
85%
N.A.
55%
70%
100%
Relative tank size required to yield driving range equivalent to gas
Tank is 1.25 times larger
Tank is 3.5 times larger
Tank is 1.8 times larger
Tank is 1.5 times larger
Pressure
200 PSI
3,000–3,600 PSI
N.A.
N.A.
N.A.
Cold weather capability
Good
Good
Poor
Poor
Good
Vehicle power
5–10% power loss
10–20% power loss
4% power increase
5% power increase
Standard
Toxicity
Nontoxic
Nontoxic
Highly toxic
Toxic
Toxic
Corrosiveness
Noncorrosive
Noncorrosive
Corrosive
Corrosive
Minimally corrosive
Source
Natural gas/ petroleum refining
Natural gas/crude oil
Natural gas/coal
Sugar and starch crops/biomass
Crude oil
CHART 67–2 The characteristics of alternative fuels compared to regular unleaded gasoline shows that all have advantages and disadvantages.
DIESEL
COAL FISCHERTROPSCH SYNTHESIS
REFINING
LPG NAPTHA
GASIFIER
FIGURE 67–15 A Fischer-Tropsch processing plant is able to produce a variety of fuels from coal.
FISCHER-TROPSCH
Synthetic fuels were first developed using the Fischer-Tropsch method and have been in use since the 1920s to convert coal, natural gas, and other fossil fuel products into a fuel that is high in quality and clean-burning. The process for producing Fischer-Tropsch fuels was patented by two German scientists, Franz Fischer and Hans Tropsch, during World War I. The Fischer-Tropsch method uses carbon monoxide and hydrogen (the same synthesis gas used to produce hydrogen fuel) to convert coal and other hydrocarbons to liquid fuels in a process similar to hydrogenation, another method for hydrocarbon conversion. The process using natural gas, also called gas-to-liquid (GTL) technology, uses a catalyst, usually iron or cobalt, and incorporates steam re-forming to give off the by-products of carbon dioxide, hydrogen, and carbon monoxide. SEE FIGURE 67–15. Whereas traditional fuels emit environmentally harmful particulates and chemicals, namely sulfur compounds, Fischer-Tropsch fuels combust with no soot or odors and emit only low levels of toxins. Fischer-Tropsch fuels can also be blended with traditional
transportation fuels with little equipment modification, as they use the same engine and equipment technology as traditional fuels. The fuels contain a very low sulfur and aromatic content and they produce virtually no particulate emissions. Researchers also expect reductions in hydrocarbon and carbon monoxide emissions. Fischer-Tropsch fuels do not differ in fuel performance from gasoline and diesel. At present, Fischer-Tropsch fuels are very expensive to produce on a large scale, although research is under way to lower processing costs. Diesel fuel created using the Fischer-Tropsch diesel (FTD) process is often called GTL diesel. GTL diesel can also be combined with petroleum diesel to produce a GTL blend. This fuel product is currently being sold in Europe and plans are in place to introduce it in North America.
COAL TO LIQUID (CTL)
Coal is very abundant in the United States and coal can be converted to a liquid fuel through a process called coal to liquid (CTL). The huge cost is the main obstacle to these plants. The need to invest $1.4 billion per plant before it can make
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product is the reason no one has built a CTL plant yet in the United States. Investors need to be convinced that the cost of oil is going to remain high in order to get them to commit this kind of money. A large plant might be able to produce 120,000 barrels of liquid fuel a day and would consume about 50,000 tons of coal per day. However, such a plant would create about 6,000 tons of CO2 per day. These CO2 emissions, which could contribute to global warming, and the cost involved make CTL a technology that is not likely to expand. Two procedures can be used to convert coal-to-liquid fuel: 1. Direct. In the direct method, coal is broken down to create liquid products. First the coal is reacted with hydrogen (H2) at high temperatures and pressure with a catalyst. This process creates a synthetic crude, called syncrude, which is then refined to produce gasoline or diesel fuel. 2. Indirect. In the indirect method, coal is first turned into a gas and the molecules are reassembled to create the desired product. This process involves turning coal into a gas called syn-gas. The syn-gas is then converted into liquid, using the Fischer-Tropsch (FT) process. Russia has been using CTL by injecting air into the underground coal seams. Ignition is provided and the resulting gases are trapped and converted to liquid gasoline and diesel fuel through the FischerTropsch process. This underground method is called underground coal gasification (UCG).
METHANOL TO GASOLINE Exxon Mobil has developed a process for converting methanol (methyl alcohol) into gasoline in a process called methanol-to-gasoline (MTG). The MTG process was discovered by accident when a gasoline additive made from methanol was being created. The process instead created olefins (alkenes), paraffins (alkenes), and aromatic compounds, which in combination are known as gasoline. The process uses a catalyst and is currently being produced in New Zealand.
compressed natural gas or other similar alternative fuels, synthetic fuels represent the lowest cost.
SAFETY PROCEDURES WHEN WORKING WITH ALTERNATIVE FUELS All fuels are flammable and many are explosive under certain conditions. Whenever working around compressed gases of any kind (CNG, LNG, propane, or LPG), always wear personal protective equipment (PPE), including at least the following items: 1. Safety glasses and/or face shield. 2. Protective gloves. 3. Long-sleeved shirt and pants to help protect bare skin from the freezing effects of gases under pressure in the event that the pressure is lost. 4. If any fuel gets on the skin, the area should be washed immediately. 5. If fuel spills on clothing, change into clean clothing as soon as possible. 6. If fuel spills on a painted surface, flush the surface with water and air dry. If simply wiped off with a dry cloth, the paint surface could be permanently damaged. 7. As with any fuel-burning vehicle, always vent the exhaust to the outside. If methanol fuel is used, the exhaust contains formaldehyde, which has a sharp odor and can cause severe burning of the eyes, nose, and throat.
FUTURE OF SYNTHETIC FUELS
Producing gasoline and diesel fuels by other methods besides refining from crude oil has usually been more expensive. With the increasing cost of crude oil, alternative methods are now becoming economically feasible. Whether or not the diesel fuel or gasoline is created from coal, natural gas, or methanol, or created by refining crude oil, the transportation and service pumps are already in place. Compared to using
WARNING Do not smoke or have an open flame in the area when working around or refueling any vehicle.
REVIEW QUESTIONS 1. Ethanol is also known by what other terms? 2. The majority of ethanol in the United States is made from what farm products? 3. How is a flexible fuel vehicle identified? 4. Methanol is also known by what other terms?
6. Why is it desirable to fill a compressed natural gas (CNG) vehicle with the highest pressure available? 7. P-series fuel is made of what products? 8. The Fischer-Tropsch method can be used to change what into gasoline?
5. What other gases are often mixed with propane?
CHAPTER QUIZ 1. Ethanol can be produced from what products? a. Switchgrass b. Corn c. Sugarcane d. Any of the above
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2. E85 means that the fuel is made from ______________. a. 85% gasoline, 15% ethanol b. 85% ethanol, 15% gasoline c. Ethanol that has 15% water d. Pure ethyl alcohol
3. A flex-fuel vehicle can be identified by ______________. a. Emblems on the side, front, and/or rear of the vehicle b. VECI c. VIN d. Any of the above 4. Methanol is also called ______________. a. Methyl alcohol c. Methyl hydrate b. Wood alcohol d. All of the above 5. Which alcohol is dangerous (toxic)? a. Methanol c. Both ethanol and methanol b. Ethanol d. Neither ethanol nor methanol 6. Which is the most widely used alternative fuel? a. E85 c. CNG b. Propane d. M85
8. How much compressed natural gas (CNG) does it require to achieve the energy of one gallon of gasoline? a. 130 cubic feet c. 105 cubic feet b. 122 cubic feet d. 91 cubic feet 9. When refueling a CNG vehicle, why is it recommended that the tank be filled to a high pressure? a. The range of the vehicle is increased b. The cost of the fuel is lower c. Less of the fuel is lost to evaporation d. Both a and c 10. Producing liquid fuel from coal or natural gas usually uses which process? a. Syncrude c. Fischer-Tropsch b. P-series d. Methanol to gasoline (MTG)
7. Liquefied petroleum gas (LPG) is also called ______________. a. E85 c. Propane b. M85 d. P-series fuel
chapter
68
DIESEL AND BIODIESEL FUELS
OBJECTIVES: After studying Chapter 68, the reader should be able to: • Explain diesel fuel specifications. • List the advantages and disadvantages of biodiesel. • Discuss API gravity. • Explain E-diesel specifications. KEY TERMS: API gravity 778 • ASTM 778 • B20 780 • Biodiesel 779 • Cetane number 777 • Cloud point 777 • Diesohol 780 • E-diesel 780 • Petrodiesel 780 • PPO 780 • SVO 780 • UCO 780 • ULSD 779 • WVO 780
Low-temperature fluidity. Diesel fuel must be able to flow freely at all expected ambient temperatures. One specification for diesel fuel is its “pour point,” which is the temperature below which the fuel would stop flowing.
Cloud point is another concern with diesel fuel at lower temperatures. Cloud point is the low-temperature point when the waxes present in most diesel fuels tend to form crystals that can clog the fuel filter. Most diesel fuel suppliers distribute fuel with the proper pour point and cloud point for the climate conditions of the area.
DIESEL FUEL FEATURES OF DIESEL FUEL
Diesel fuel must meet an entirely different set of standards than gasoline. Diesel fuel contains 12% more heat energy than the same amount of gasoline. The fuel in a diesel engine is not ignited with a spark, but is ignited by the heat generated by high compression. The pressure of compression (400 to 700 PSI or 2,800 to 4,800 kPa) generates temperatures of 1,200°F to 1,600°F (700°C to 900°C), which speeds the preflame reaction to start the ignition of fuel injected into the cylinder.
DIESEL FUEL REQUIREMENTS
All diesel fuel must have the
following characteristics:
Cleanliness. It is imperative that the fuel used in a diesel engine be clean and free from water. Unlike the case with gasoline engines, the fuel is the lubricant and coolant for the diesel injector pump and injectors. Good-quality diesel fuel contains additives such as oxidation inhibitors, detergents, dispersants, rust preventatives, and metal deactivators.
CETANE NUMBER
The cetane number for diesel fuel is the opposite of the octane number for gasoline. The cetane number is a measure of the ease with which the fuel can be ignited. The cetane rating of the fuel determines, to a great extent, its ability to start the engine at low temperatures and to provide smooth warm-up and even combustion. The cetane rating of diesel fuel should be between 45 and 50. The higher the cetane rating, the more easily the fuel is ignited.
SULFUR CONTENT The sulfur content of diesel fuel is very important to the life of the engine. Sulfur in the fuel creates sulfuric
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FREQUENTLY ASKED QUESTION
How Can You Tell If Gasoline Has Been Added to the Diesel Fuel by Mistake? If gasoline has been accidentally added to diesel fuel and is burned in a diesel engine, the result can be very damaging to the engine. The gasoline can ignite faster than diesel fuel, which would tend to increase the temperature of combustion. This high temperature can harm injectors and glow plugs, as well as pistons, head gaskets, and other major diesel engine components. If contaminated fuel is suspected, first smell the fuel at the filler neck. If the fuel smells like gasoline, then the tank should be drained and refilled with diesel fuel. If the smell test does not indicate a gasoline smell (or any rancid smell), then test a sample for proper API gravity.
(a)
NOTE: Diesel fuel designed for on-road use should be green in color. Red diesel fuel (high sulfur) should be found only in off-road or farm equipment.
GRADE #2
This grade has a higher boiling point, cloud point, and pour point as compared with grade #1. It is usually specified where constant speed and high loads are encountered, such as in long-haul trucking and automotive diesel applications. Most diesel is Grade #2.
DIESEL FUEL SPECIFIC GRAVITY TESTING
(b)
FIGURE 68–1 (a) Regular diesel fuel on the left has a clear or greenish tint, whereas fuel for off-road use is tinted red for identification. (b) A fuel pump in a farming area that clearly states the red diesel fuel is for off-road use only.
The density of diesel fuel should be tested whenever there is a driveability concern. The density or specific gravity of diesel fuel is measured in units of API gravity. API gravity is an arbitrary scale expressing the gravity or density of liquid petroleum products devised jointly by the American Petroleum Institute and the National Bureau of Standards. The measuring scale is calibrated in terms of degrees API. Oil with the least specific gravity has the highest API gravity. The formula for determining API gravity is as follows: Degrees API gravity (141.5 specific gravity at 60°F) 131.5
acid during the combustion process, which can damage engine components and cause piston ring wear. Federal regulations are getting extremely tight on sulfur content to less than 15 parts per million (ppm). High-sulfur fuel contributes to acid rain.
DIESEL FUEL COLOR
Diesel fuel intended for use on the streets and highways is clear or green in color. Diesel fuel to be used on farms and off-road use is dyed red. SEE FIGURE 68–1.
GRADES OF DIESEL FUEL
American Society for Testing Materials (ASTM) also classifies diesel fuel by volatility (boiling range) into the following grades: GRADE #1
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This grade of diesel fuel has the lowest boiling point and the lowest cloud and pour points, as well as a lower BTU content—less heat per pound of fuel. As a result, grade #1 is suitable for use during low-temperature (winter) operation. Grade #1 produces less heat per pound of fuel compared to grade #2 and may be specified for use in diesel engines involved in frequent changes in load and speed, such as those found in city buses and delivery trucks.
CHAPTER 68
The normal API gravity for #1 diesel fuel is 39 to 44 (typically 40). The normal API gravity for #2 diesel fuel is 30 to 39 (typically 35). A hydrometer calibrated in API gravity units should be used to test diesel fuel. SEE FIGURE 68–2. SEE CHART 68–1 for a comparison among specific gravity, weight density, pounds per gallon, and API gravity of diesel fuel.
DIESEL FUEL HEATERS Diesel fuel heaters, either coolant or electric, help prevent power loss and stalling in cold weather. The heater is placed in the fuel line between the tank and the primary filter. Some coolant heaters are thermostatically controlled, which allows fuel to bypass the heater once it has reached operating temperature. SEE FIGURE 68–3. ULTRA-LOW-SULFUR DIESEL FUEL Diesel fuel is used in diesel engines and is usually readily available throughout the United States, Canada, and Europe, where many more cars are equipped with diesel engines. Diesel engines manufactured to 2007 or newer standards must use ultra-low-sulfur diesel fuel containing less than 15 ppm of sulfur compared to the older, low-sulfur specification of 500 ppm. The purpose of the lower sulfur amount in diesel fuel is to
API GRAVITY COMPARISON CHART Values for API Scale Oil
FIGURE 68–2 Testing the API viscosity of a diesel fuel sample using a hydrometer.
FUEL FILTER CAP WATER DRAIN
FIGURE 68–3 A fuel heater is part of the fuel filter and water separator located on the frame rail of a Ford pickup truck equipped with a PowerStroke 6.0 liter V-8 diesel engine. reduce emissions of sulfur oxides (SOx) and particulate matter (PM) from heavy-duty highway engines and vehicles that use diesel fuel. The emission controls used on 2007 and newer diesel engines require the use of ultra-low-sulfur diesel (ULSD) for reliable operation. Ultra-low-sulfur diesel (ULSD) will eventually replace the current highway diesel fuel, low-sulfur diesel, which can have as much as 500 ppm of sulfur. ULSD is required for use in all model year 2007 and newer vehicles equipped with advanced emission control systems. ULSD looks lighter in color and has less smell than other diesel fuel.
BIODIESEL DEFINITION OF BIODIESEL Biodiesel is a domestically produced, renewable fuel that can be manufactured from vegetable oils, animal fats, or recycled restaurant greases. Biodiesel is safe, biodegradable, and reduces serious air pollutants such as particulate matter (PM), carbon monoxide, and hydrocarbons. Biodiesel is
API GRAVITY SCALE
SPECIFIC GRAVITY
WEIGHT DENSITY, LB/FT
POUNDS PER GALLON
0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 60 62 64 66 68 70 72 74 76 78 80 82 84 86 88 90 92 94 96 98 100
1.0000 0.9861 0.9725 0.9593 0.9465 0.9340 0.9218 0.9100 0.8984 0.8871 0.8762 0.8654 0.8550 0.8448 0.8348 0.8251 0.8155 0.8030 0.7972 0.7883 0.7796 0.7711 0.7628 0.7547 0.7467 0.7389 0.7313 0.7238 0.7165 0.7093 0.7022 0.6953 0.6886 0.6819 0.6754 0.6690 0.6628 0.6566 0.6506 0.6446 0.6388 0.6331 0.6275 0.6220 0.6116 0.6112
62.36 61.50 60.65 59.83 59.03 58.25 57.87 56.75 56.03 55.32 54.64 53.97 53.32 52.69 51.06 50.96 50.86 50.28 49.72 49.16 48.62 48.09 47.57 47.07 46.57 46.08 45.61 45.14 44.68 44.23 43.79 43.36 42.94 42.53 41.12 41.72 41.33 40.95 40.57 40.20 39.84 39.48 39.13 38.79 38.45 38.12
8.337 8.221 8.108 7.998 7.891 7.787 7.736 7.587 7.490 7.396 7.305 7.215 7.128 7.043 6.960 6.879 6.799 6.722 6.646 6.572 6.499 6.429 6.359 6.292 6.225 6.160 6.097 6.034 5.973 5.913 5.854 5.797 5.741 5.685 5.631 5.577 5.526 5.474 5.424 5.374 5.326 5.278 5.231 5.186 5.141 5.096
CHART 68–1 The API gravity scale is based on the specific gravity of the fuel.
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FREQUENTLY ASKED QUESTION
I Thought Biodiesel Was Vegetable Oil? Biodiesel is vegetable oil with the glycerin component removed by means of reacting the vegetable oil with a catalyst. The resulting hydrocarbon esters are 16 to 18 carbon atoms in length, almost identical to the petroleum diesel fuel atoms. This allows the use of biodiesel fuel in a diesel engine with no modifications needed. Biodiesel-powered vehicles do not need a second fuel tank, whereas vegetableoil-powered vehicles do. There are three main types of fuel used in diesel engines. These are:
FIGURE 68–4 A pump decal indicating that the biodiesel fuel is ultra-low-sulfur diesel (ULSD) and must be used in 2007 and newer diesel vehicles. defined as mono-alkyl esters of long-chain fatty acids derived from vegetable oils or animal fats which conform to ASTM D6751 specifications for use in diesel engines. Biodiesel refers to the pure fuel before blending with diesel fuel. SEE FIGURE 68–4.
BIODIESEL BLENDS Biodiesel blends are denoted as “BXX” with “XX” representing the percentage of biodiesel contained in the blend (i.e., B20 is 20% biodiesel, 80% petroleum diesel). Blends of 20% biodiesel with 80% petroleum diesel (B20) can generally be used in unmodified diesel engines; however, users should consult their OEM and engine warranty statement. Biodiesel can also be used in its pure form (B100), but it may require certain engine modifications to avoid maintenance and performance problems and may not be suitable for wintertime use. Most diesel engine or vehicle manufacturers of diesel vehicles allow the use of B5 (5% biodiesel). For example, Cummins, used in Dodge trucks, allows the use of B20 only if the optional extra fuel filter has been installed. Users should consult their engine warranty statement for more information on fuel blends of greater than 20% biodiesel. In general, B20 costs 30 to 40 cents more per gallon than conventional diesel. Although biodiesel costs more than regular diesel fuel, often called petrodiesel, fleet managers can make the switch to alternative fuels without purchasing new vehicles, acquiring new spare parts inventories, rebuilding refueling stations, or hiring new service technicians. FEATURES OF BIODIESEL
• Petroleum diesel, a fossil hydrocarbon with a carbon chain length of about 16 carbon atoms. • Biodiesel, a hydrocarbon with a carbon chain length of 16 to 18 carbon atoms. • Vegetable oil is a triglyceride with a glycerin component joining three hydrocarbon chains of 16 to 18 carbon atoms each, called straight vegetable oil (SVO). Other terms used when describing vegetable oil include: • Pure plant oil (PPO)—a term most often used in Europe to describe SVO • Waste vegetable oil (WVO)—this oil could include animal or fish oils from cooking • Used cooking oil (UCO)—a term used when the oil may or may not be pure vegetable oil Vegetable oil is not liquid enough at common ambient temperatures for use in a diesel engine fuel delivery system designed for the lower-viscosity petroleum diesel fuel. Vegetable oil needs to be heated to obtain a similar viscosity to biodiesel and petroleum diesel. This means that a heat source needs to be provided before the fuel can be used in a diesel engine. This is achieved by starting on petroleum diesel or biodiesel fuel until the engine heat can be used to sufficiently warm a tank containing the vegetable oil. It also requires purging the fuel system of vegetable oil with petroleum diesel or biodiesel fuel prior to stopping the engine to avoid the vegetable oil’s thickening and solidifying in the fuel system away from the heated tank. The use of vegetable oil in its natural state does, however, eliminate the need to remove the glycerin component. Many vehicle and diesel engine fuel system suppliers permit the use of biodiesel fuel that is certified as meeting testing standards. None permit the use of vegetable oil in its natural state.
Biodiesel has the following
characteristics: 1. Purchasing biodiesel in bulk quantities decreases the cost of fuel. 2. Biodiesel maintains similar horsepower, torque, and fuel economy.
E-DIESEL FUEL
3. Biodiesel has a higher cetane number than conventional diesel, which increases the engine’s performance.
DEFINITION OF E-DIESEL
4. It is nontoxic, which makes it safe to handle, transport, and store. Maintenance requirements for B20 vehicles and petrodiesel vehicles are the same. 5. Biodiesel acts as a lubricant and this can add to the life of the fuel system components. NOTE: For additional information on biodiesel and the locations where it can be purchased, visit www.biodiesel.org.
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E-diesel, also called diesohol outside of the United States, is standard No. 2 diesel fuel that contains up to 15% ethanol. While E-diesel can have up to 15% ethanol by volume, typical blend levels are from 8% to 10%.
CETANE RATING OF E-DIESEL The higher the cetane number, the shorter the delay between injection and ignition. Normal diesel fuel has a cetane number of about 50. Adding 15% ethanol lowers the cetane number. To increase the cetane number back
to that of conventional diesel fuel, a cetane-enhancing additive is added to E-diesel. The additive used to increase the cetane rating of E-diesel is ethylhexylnitrate or ditertbutyl peroxide. E-diesel has better cold-flow properties than conventional diesel. The heat content of E-diesel is about 6% less than conventional diesel, but the particulate matter (PM) emissions are reduced by as
much as 40%, 20% less carbon monoxide, and a 5% reduction in oxides of nitrogen (NOX). Currently, E-diesel is considered to be experimental and can be used legally in off-road applications or in mass-transit buses with EPA approval. For additional information, visit www.e-diesel.org.
REVIEW QUESTIONS 1. What is meant by the cloud point?
3. Biodiesel blends are identified by what designation?
2. What is ultra-low-sulfur diesel?
CHAPTER QUIZ 1. What color is diesel fuel dyed if it is for off-road use only? a. Red c. Blue b. Green d. Yellow
6. E-diesel is diesel fuel with what additive? a. Methanol c. Ethanol b. Sulfur d. Vegetable oil
2. What clogs fuel filters when the temperature is low on a vehicle that uses diesel fuel? a. Alcohol c. Wax b. Sulfur d. Cetane
7. Biodiesel is regular diesel fuel with vegetable oil added. a. True b. False
3. The specific gravity of diesel fuel is measured in what units? a. Hydrometer units c. Grade number b. API gravity d. Cetane number 4. What rating of diesel fuel indicates how well a diesel engine will start? a. Specific gravity rating c. Cloud point b. Sulfur content d. Cetane rating 5. Ultra-low-sulfur diesel fuel has how much sulfur content? a. 15 ppm c. 500 ppm b. 50 ppm d. 1,500 ppm
chapter
69
8. B20 biodiesel has how much regular diesel fuel? a. 20% c. 80% b. 40% d. 100% 9. Most diesel fuel is what grade? a. Grade #1 c. Grade #3 b. Grade #2 d. Grade #4 10. Most manufacturers of vehicles equipped with diesel engines allow what type of biodiesel? a. B100 c. B20 b. B80 d. B5
IGNITION SYSTEM COMPONENTS AND OPERATION
OBJECTIVES: After studying Chapter 69, the reader will be able to: • Prepare for ASE Engine Performance (A8) certification test content area “B” (Ignition System Diagnosis and Repair). • Explain how ignition coils create 40,000 volts. • Discuss crankshaft position sensor and pickup coil operation. • Describe the operation of waste-spark and coil-on-plug ignition systems. KEY TERMS: Bypass ignition 792 • Companion (paired) cylinder 787 • Compression-sensing ignition 788 • COP ignition 788 • Detonation 791 • DI 782 • DIS 787 • Dwell 792 • EI 782 • EMI 788 • EST 792 • Firing order 786 • Hall effect 784 • High voltage 786 • IC 792 • ICM 791 • Ion-sensing ignition 790 • Low voltage 786 • Knock sensors 791 • Magnetic sensor 784 • Optical sensors 785 • Paired cylinders 785 • Pickup coil 784 • Ping 791 • Primary winding 783 • Pulse generator 784 • Secondary winding 783 • Schmitt trigger 785 • Spark knock 791 • SPOUT 792 • Switching 783 • Transistor 784 • Trigger 784 • Turns ratio 783 • Up-integrated ignition 793
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IGNITION SYSTEM
POINTS
DISTRIBUTOR CAM
PURPOSE AND FUNCTION
The ignition system includes components and wiring necessary to create and distribute a high voltage (up to 40,000 volts or more) and send to the spark plug at the correct time. A high-voltage arc occurs across the gap of a spark plug inside the combustion chamber. The spark raises the temperature of the air-fuel mixture and starts the combustion process inside the cylinder.
BACKGROUND All ignition systems apply battery voltage (close to 12 volts) to the positive side of the ignition coil(s) and pulse the negative side to ground on and off.
Early ignition systems. Before the mid-1970s, ignition systems used a mechanically opened set of contact points to make and break the electrical connection to ground. A cam lobe, located in and driven by the distributor, opened the points. There was one lobe for each cylinder. The points used a rubbing block that was lubricated by applying a thin layer of grease on the cam lobe at each service interval. Each time the points opened, a spark was created in the ignition coil. The high-voltage spark then traveled to each spark plug through the distributor cap and rotor and the spark plug wires. The distributor was used twice in the creation of the spark.
First, it connected to the camshaft that rotated the distributor cam causing the points to open and close.
Second, it used a rotor to direct the high-voltage spark from the coil entering the center of the distributor cap to inserts connected to spark plug wires to each cylinder.
SEE FIGURE 69–1.
CONDENSER
FIGURE 69–1 A point-type distributor from a hot rod being tested on a distributor machine.
Current (approximately 2 to 6 amperes) flows in the primary coil creating a magnetic field.
When the ground is opened by the ICM, the primary circuit is turned off and the built-up magnetic field in the secondary winding collapses.
The movement of the collapsing magnetic field induces a voltage of 250 to 400 volts in the primary winding and 20,000 to 40,000 volts or more in the secondary winding with a current of 0.02 to 0.08 amperes (20 to 80 mA).
The high voltage created in the secondary winding is high enough to jump the air gap at the spark plug.
The electrical arc at the spark plug ignites the air-fuel mixture in the combustion chamber of the engine.
For each spark that occurs, the coil must be charged with a magnetic field and then discharged.
Electronic ignition. Since the mid-1970s, ignition systems have used sensors, such as a pickup coil and reluctor (trigger wheel), to trigger or signal an electronic module that switches the primary ground circuit of the ignition coil. Distributor ignition (DI) is the term specified by the Society of Automotive Engineers (SAE) for an ignition system that uses a distributor. Electronic ignition (EI) is the term specified by the SAE for an ignition system that does not use a distributor. Types of EI systems include:
WARNING The spark from an ignition coil is strong enough to cause physical injury. Always follow the exact service procedure and avoid placing hands near the secondary ignition components when the engine is running.
1. Waste-spark system. This type of system uses one ignition coil to fire the spark plugs for two cylinders at the same time. 2. Coil-on-plug system. This type of system uses a single ignition coil for each cylinder with the coil placed above or near the spark plug.
IGNITION COIL OPERATION
In an ignition coil there are two
The ignition components in the coil primary winding are known collectively as the primary ignition circuit.
When the primary circuit is carrying current, the secondary circuit is off.
When the primary circuit is turned off, the secondary circuit has high voltage.
The components necessary to create and distribute the high voltage produced in the secondary windings of the coil are called the secondary ignition circuit. SEE FIGURE 69–2.
windings:
Primary winding
Secondary winding
All ignition systems use electromagnetic induction to produce a high-voltage spark from the ignition coil. Electromagnetic induction means that a current can be created in a conductor (coil winding) by a moving magnetic field. Current flowing through the primary winding of the coil produces the magnetic field in an ignition coil. An ignition coil is able to increase battery voltage to 40,000 volts or more in the following way.
These circuits include the following components.
Primary ignition circuit 1. Battery
Battery voltage is applied to the primary winding.
2. Ignition switch
A ground is provided to the primary winding by the ignition control module (ICM), igniter, or powertrain control module (PCM).
3. Primary winding of coil
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4. Pickup coil (if distributor ignition)
BATTERY (B+) IGN. SW.
COIL
SECONDARY
PRIMARY
IGNITION MODULE
SPARK PLUG
BATTERY (B+) IGN. SW.
COIL
OR
FIGURE 69–3 The steel laminations used in an E coil helps increase the magnetic field strength, which helps the coil produce higher energy output for a more complete combustion in the cylinders.
SECONDARY
PRIMARY
SPARK PLUG
IGNITION MODULE
SECONDARY TERMINAL
SECONDARY WINDING
SPARK PLUG
FIGURE 69–2 The primary ignition system is used to trigger and therefore create the secondary (high-voltage) spark from the ignition coil. Some ignition coils are electrically connected, called married (top figure) whereas others use separated primary and secondary windings, called divorced (lower figure). 5. Crankshaft position sensor (CKP) 6. Ignition control module (ICM) or igniter
PRIMARY WINDING
Secondary ignition circuit 1. Secondary winding of coil 2. Distributor cap and rotor (if the vehicle is so equipped)
FIGURE 69–4 The primary windings are inside the secondary windings on this General Motors coil.
3. Spark plug wires 4. Spark plugs
IGNITION COIL CONSTRUCTION Many ignition coils contain two separate but electrically connected windings of copper wire. Other coils are true transformers in which the primary and secondary windings are not electrically connected. SEE FIGURE 69–3. The center of an ignition coil contains a core of laminated soft iron (thin strips of soft iron). This core increases the magnetic strength of the coil.
Secondary winding. Surrounding the laminated core are approximately 20,000 turns of fine wire (approximately 42 gauge), which is smaller than a human hair. The winding is called the secondary coil winding. Primary winding. Surrounding the secondary windings are approximately 150 turns of heavy wire (approximately 21 gauge), which is about 0.028 inch in diameter. The winding is called the primary coil winding. The secondary winding has about 100 times the number of turns of the primary winding, referred to as the turns ratio (approximately 100:1).
In older coils, these windings are surrounded with a thin metal shield and insulating paper and placed into a metal container filled with transformer oil to help cool the coil windings. Other coil designs use an air-cooled, epoxy-sealed E coil. The E coil is so named because the laminated, soft iron core is E shaped, with the coil wire turns wrapped around the center “finger” of the E and the primary winding wrapped inside the secondary winding. SEE FIGURES 69–4 AND 69–5.
IGNITION SWITCHING AND TRIGGERING SWITCHING
For any ignition system to function, the primary current must be turned on to charge the coil and off to allow the coil to discharge, creating a high-voltage spark. This turning on and off of the primary circuit is called switching. The unit that does the
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switching is an electronic switch, such as a power transistor. This power transistor can be located in either of the following locations.
In the ICM or igniter
In the PCM (computer)
The primary circuit current switching is controlled by a transistor (electronic switch) inside the ignition module or igniter, and is controlled by one of the following devices.
NOTE: On some coil-on-plug systems, the ICM is part of the ignition coil itself and is serviced as an assembly.
PRIMARY CIRCUIT OPERATION
The device that signals the switching of the coil on and off or just on in most instances is called the trigger. A trigger is typically a pickup coil in some distributortype ignitions and a crankshaft position sensor (CKP) on electronic systems (waste-spark and coil-on-plug systems). To get a spark out of an ignition coil, the primary coil circuit must be turned on and off.
SECONDARY
PRIMARY
3 4
IGNITION SWITCH
COIL
CMP SENSOR ICM
Magnetic crankshaft position sensors use the changing strength of the magnetic field surrounding a coil of wire to signal the ICM and PCM. This signal is used by the electronics in the ignition module and computer to determine piston position and engine speed (RPM). This sensor operates similarly to the distributor magnetic pickup coil. The crankshaft position sensor uses the strength of the magnetic field surrounding a coil of wire to signal the ICM. The rotating crankshaft has notches cut into it that trigger the magnetic position sensor, which change the strength of the magnetic field as the notches pass by the position sensor, creating an AC analog signal. SEE FIGURE 69–7.
6 5 8 1
8
7
6
5
4
3
2
1
7 2
CKP SENSOR
PCM
FIGURE 69–5 The primary ignition system is used to trigger and therefore create the secondary (high-voltage) spark from the ignition coil.
Magnetic sensor. A simple and common ignition electronic switching device is the magnetic pulse generator system. This type of magnetic sensor is often called a magnetic pulse generator or pickup coil, and is installed in the distributor housing. The pulse generator consists of a trigger wheel (reluctor) and a pickup coil. The pickup coil consists of an iron core wrapped with fine wire, in a coil at one end and attached to a permanent magnet at the other end. The center of the coil is called the pole piece. The pickup coil signal triggers the transistor inside the module and is also used by the computer for piston position information and engine speed (RPM). The reluctor is shaped so that the magnetic strength changes enough to create a usable varying signal for use by the module to trigger the coil. A magnetic pickup coil produces an analog AC signal. SEE FIGURE 69–6.
Hall-effect switch. This switch also uses a stationary sensor and rotating trigger wheel (shutter). Unlike the magnetic pulse generator, the Hall-effect switch requires a small input voltage to generate an output or signal voltage. Hall effect has the ability to generate a voltage signal in semiconductor material (gallium arsenate crystal) by passing
ROTATING FERROUS METAL RELUCTOR
NARROW GAP RESULTS IN STRONG MAGNETIC FIELD FOR COIL ⴙ ⴚ
PERMANENT MAGNET
WIDE GAP OFFERS WEAK MAGNETIC FIELD FOR COIL ⴙ ⴚ
PERMANENT MAGNET
VOLTAGE REVERSES AS STAR WHEEL MOVES PAST CLOSEST POINT
0
FIGURE 69–6 Operation of a typical pulse generator (pickup coil). At the bottom is a line drawing of a typical scope pattern of the output voltage of a pickup coil. The ICM receives this voltage from the pickup coil and opens the ground circuit to the ignition coil when the voltage starts down from its peak (just as the reluctor teeth start moving away from the pickup coil).
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ⴙ
+5 V
MAXIMUM POSITIVE SWING
HALL EFFECT SENSOR
ⴙ
OV
1K TRIGGER WHEEL
ⴚ
+5 V SIGNAL
0V
ⴚ
ⴙ ⴙ
OV
GROUND SWINGS THROUGH ZERO VOLTS
FIGURE 69–8 A Hall-effect sensor produces an on-off voltage signal whether it is used with a blade or a notched wheel.
ⴚ
TECH TIP
ⴚ ⴙ
The Tachometer Trick
ⴙ
OV ⴚ
ⴚ
MAXIMUM NEGATIVE SWING
FIGURE 69–7 A magnetic sensor uses a permanent magnet surrounded by a coil of wire. The notches of the crankshaft (or camshaft) create a variable magnetic field strength around the coil. When a metallic section is close to the sensor, the magnetic field is stronger because metal is a better conductor of magnetic lines of force than air.
current through it in one direction and applying a magnetic field to it at a right angle to its surface. If the input current is held steady and the magnetic field fluctuates, an output voltage is produced that changes in proportion to field strength. Most Hall-effect switches used in distributors have the following:
When diagnosing a no-start or intermediate misfiring condition, check the operation of the tachometer. If the tachometer does not indicate engine speed (no-start condition) or drops toward zero (engine missing), then the problem is due to a defect in the primary ignition circuit. The tachometer gets its signal from the pulsing of the primary winding of the ignition coil. The following components in the primary circuit could cause the tachometer to not work when the engine is cranking. • • • •
Pickup coil Crankshaft position (CKP) sensor Ignition control module (ICM) or igniter Coil primary wiring
If the vehicle is not equipped with a tachometer, use a scan tool to look at engine RPM. Results: • No or an unstable engine RPM reading means the problem is in the primary ignition circuit. • A steady engine RPM reading means the problem is in the secondary ignition circuit or is a fuel-related problem.
1. Hall element or device 2. Permanent magnet 3. Rotating ring of metal blades (shutters) similar to a trigger wheel (Another method uses a stationary sensor with a rotating magnet.) SEE FIGURE 69–8. Some blades are designed to hang down, typically found in Bosch and Chrysler systems; others may be on a separate ring on the distributor shaft, typically found in General Motors and Ford Halleffect distributors.
When the shutter blade enters the gap between the magnet and the Hall element, it creates a magnetic shunt that changes the field strength through the Hall element.
This analog signal is sent to a Schmitt trigger inside the sensor itself, which converts the analog signal into a digital signal. A digital (on or off) voltage signal is created at a varying frequency to the ignition module or onboard computer. SEE FIGURE 69–9.
Optical sensors. This type of sensor uses light from an LED and a phototransistor to signal the computer. An
interrupter disc between the LED and the phototransistor has slits that allow the light from the LED to trigger the phototransistor on the other side of the disc. Most optical sensors (usually located inside the distributor) use two rows of slits to provide individual cylinder recognition (low-resolution) and precise distributor angle recognition (high-resolution) signals that are used for cylinder misfire detection. SEE FIGURE 69–10.
DISTRIBUTOR IGNITION PURPOSE AND FUNCTION
The purpose of a distributor is to distribute the high-voltage spark from the secondary terminal of the ignition coil to the spark plugs for each cylinder. A gear or shaft that is part of the distributor is meshed with a gear on the camshaft. The distributor is driven at camshaft speed (one-half of crankshaft speed).
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HALL-EFFECT REFERENCE CAMSHAFT SENSOR REFERENCE FOR CYL #5
HALL-EFFECT CRANKSHAFT POSITION SENSOR
REFERENCE FOR CYL #4
REFERENCE FOR CYL #6
TORQUE CONVERTER DRIVE PLATE
REFERENCE FOR CYL #3
SLOTS
REFERENCE FOR CYL #2
REFERENCE FOR CYL #1
PAPER SPACER PAPER SPACER
CRANK SENSOR ELECTRICAL CONNECTOR O-RING CAM SENSOR ELECTRICAL CONNECTOR
CAM TDC-2
TDC-3
TDC-5
TDC-4
TDC-6
TDC-1
CRANK
FIGURE 69–9 Some Hall-effect sensors look like magnetic sensors. This Hall-effect camshaft reference sensor and crankshaft position sensor have an electronic circuit built in that creates a 0 to 5 volt signal as shown at the bottom. These Hall-effect sensors have three wires: a power supply (8 volts) from the computer (controller), a signal (0 to 5 volts), and a signal ground.
180° SIGNAL SLIT FOR NO. 1 CYLINDER
ROTOR PLATE
1° SIGNAL SLIT CRANK ANGLE SENSOR
180° SIGNAL SLIT
ROTOR PLATE
ROTOR SHAFT (b)
(a)
FIGURE 69–10 (a) Typical optical distributor. (b) Cylinder I slit signals the computer the piston position for cylinder I. The 1-degree slits provide accurate engine speed information to the PCM.
Most distributor ignition systems also use a sensor to trigger the ignition control module.
OPERATION OF DISTRIBUTOR IGNITION
The first time is when the low voltage triggers the ignition control module (ICM) by the use of the rotating distributor shaft.
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The second time is when the high voltage is directed by rotating the rotor to distribute the high-voltage spark to the individual spark plugs.
The distributor is
used twice in most ignition systems that use one.
FIRING ORDER Firing order means the order that the spark is distributed to the correct spark plug at the right time. The firing order of an engine is determined by crankshaft and camshaft
FIGURE 69–12 The firing order is cast or stamped on the intake manifold on most engines that have a distributor ignition. FIGURE 69–11 A light shield being installed before the rotor is attached.
WASTE-SPARK IGNITION SYSTEMS TECH TIP Optical Distributors Do Not Like Light Optical distributors use the light emitted from LEDs to trigger phototransistors. Most optical distributors use a shield between the distributor rotor and the optical interrupter ring. Sparks jump the gap from the rotor tip to the distributor cap inserts. This shield blocks the light from the electrical arcs from interfering with the detection of the light from the LEDs. If this shield is not replaced during service, the light signals are reduced and the engine may not operate correctly. SEE FIGURE 69–11. This can be difficult to detect because nothing looks wrong during a visual inspection. Remember that all optical distributors must be shielded between the rotor and the interrupter ring.
design and the location of the spark plug wires in the distributor cap of an engine equipped with a distributor. The firing order is often cast into the intake manifold for easy reference. SEE FIGURE 69–12. Service information also shows the firing order and the direction of the distributor rotor rotation, engine cylinder numbering, and the location of the spark plug wires on the distributor cap. CAUTION: Ford V-8s use two different firing orders depending on whether the engine is high output (HO) or standard. Using the incorrect firing order can cause the engine to backfire and could cause engine damage or personal injury. General Motors V-6 engines use different firing orders and different locations for cylinder 1 between the 60-degree V-6 and the 90-degree V-6. Using the incorrect firing order or cylinder number location chart could result in poor engine operation or a no-start condition. Firing order is also important for waste-spark-type ignition systems. The spark plug wire can often be installed on the wrong coil pack which can create a no-start condition or poor engine operation.
PARTS INVOLVED Waste-spark ignition is another name for the distributorless ignition system (DIS) or electronic ignition (EI). Waste-spark ignition was introduced in the mid-1980s and uses the ignition control module (ICM) and/or the powertrain control module (PCM) to fire the ignition coils. A 4-cylinder engine uses two ignition coils and a 6-cylinder engine uses three ignition coils. Each coil is a true transformer because the primary winding and secondary winding are not electrically connected. A waste-spark coil has four terminals:
Two primary (Bat and to ICM)
Two secondary (each connected to a spark plug)
Each end of the secondary winding is connected to the spark plug of the cylinder exactly opposite the other in the firing order, called a companion (paired) cylinder. SEE FIGURE 69–13.
WASTE-SPARK SYSTEM OPERATION Both spark plugs fire at the same time (within nanoseconds of each other).
When one cylinder (for example, cylinder number 6) is on the compression stroke, the other cylinder (number 3) is on the exhaust stroke.
The spark that occurs on the exhaust stroke is called the waste spark, because it does no useful work and is only used as a ground path for the secondary winding of the ignition coil. The voltage required to jump the spark plug gap on cylinder 3 (the exhaust stroke) is only 2 to 3 kV.
The cylinder on the compression stroke uses the remaining coil energy.
One spark plug of each pair always fires straight polarity (from the center electrode to the ground electrode of the spark plug) and the other cylinder always fires reverse polarity (from the ground electrode to the center electrode of the spark plug). Spark plug life is not greatly affected by the reverse polarity. If there is only one defective spark plug wire or spark plug, two cylinders may be affected.
The coil polarity is determined by the direction the coil is wound (left-hand rule for conventional current flow) and cannot be changed. For example, if a V-6 engine has a firing order of 165432 when one cylinder is on compression, such as cylinder number 1, then the paired cylinder (number 4) is on the exhaust stroke. During the next
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PRIMARY CONTROL TRANSISTOR
FREQUENTLY ASKED QUESTION
How Can You Determine the Companion Cylinder?
IGNITION MODULE
IC IGN. FUSE B+
Companion cylinders are two cylinders in the same engine that both reach top dead center at the same time. • One cylinder is on the compression stroke. • The other cylinder is on the exhaust stroke. To determine which two cylinders are companion cylinders in the engine, follow these steps: STEP 1 Determine the firing order (such as 165432 for a typical V-6 engine). STEP 2 Write the firing order and then place the second half under the first half. 165 432
COMMON IRON
STEP 3 The cylinder numbers above and below each other are companion or paired cylinders.
CENTER ELECTRODE COMPRESSION STROKE
SIDE ELECTRODE
In this case, 1 and 4, 6 and 3, and 5 and 2 are companion cylinders.
EXHAUST STROKE
FIGURE 69–13 A waste-spark system fires one cylinder while its piston is on the compression stroke and into paired or companion cylinders while it is on the exhaust stroke. In a typical engine, it requires only about 2 to 3 kV to fire the cylinder on the exhaust stroke. The remaining coil energy is available to fire the spark plug under compression (typically about 8 to 12 kV). rotation of the crankshaft, cylinder number 4 is on the compression stroke and cylinder number 1 is on the exhaust stroke. Cylinder 1. Always fires straight polarity (from the center electrode to the ground electrode), one time requiring 10 to 12 kV, and one time requiring 3 to 4 kV. Cylinder 4. Always fires reverse polarity (from the ground electrode to the center electrode), one time requiring 10 to 12 kV, and one time requiring 3 to 4 kV. Waste-spark ignitions require a sensor (usually a crankshaft sensor) to trigger the coils at the correct time. SEE FIGURE 69–14. The crankshaft sensor cannot be moved to adjust ignition timing, because ignition timing is not adjustable. The slight adjustment of the crankshaft sensor is designed to position the sensor exactly in the middle of the rotating metal disc for maximum clearance.
COMPRESSION-SENSING WASTE-SPARK IGNITION Some waste-spark ignition systems, such as on Saturns and others, use the voltage required to fire the cylinders to determine cylinder position. It requires a higher voltage to fire a spark plug under compression than it does when the spark plug is being fired on the exhaust stroke. The electronics in the coil and the PCM can detect which of the two companion (paired) cylinders that are fired at the same time requires the higher voltage, which indicates the cylinder that is on the compression stroke. For example, a typical 4-cylinder engine equipped with a waste-spark ignition system will fire both cylinders 1 and 4. If cylinder number 4 requires a higher voltage to fire, as determined by the electronics connected to the coil, then the PCM assumes that cylinder number 4 is on the compression stroke. Engines equipped with compression-sensing ignition systems do not require the use of a camshaft position sensor to determine specific cylinder numbers. SEE FIGURE 69–15.
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TECH TIP Odds Fire Straight Waste-spark ignition systems fire two spark plugs at the same time. Most vehicle manufacturers use a waste-spark system that fires the odd number cylinders (1, 3, and 5) by straight polarity (current flow from the top of the spark plug through the gap and to the ground electrode). The even number cylinders (2, 4, and 6) are fired reverse polarity, meaning that the spark jumps from the side electrode to the center electrode. Some vehicle manufacturers equip their vehicles with platinum plugs, with the expensive platinum alloy only on one electrode as follows: • On odd number cylinders (1, 3, 5), the platinum is on the center electrode. • On even number cylinders (2, 4, 6), the platinum is on the ground electrode. Replacement spark plugs use platinum on both electrodes (double platinum) and, therefore, can be placed in any cylinder location.
COIL-ON-PLUG IGNITION TERMINOLOGY Coil-on-plug (COP) ignition uses one ignition coil for each spark plug. This system is also called coil-by-plug, coil-near-plug, or coil-over-plug ignition. SEE FIGURES 69–16 AND 69–17. ADVANTAGES
The coil-on-plug system eliminates the spark plug wires that are often the source of electromagnetic interference (EMI) that can cause problems to some computer signals. The vehicle computer controls the timing of the spark. Ignition
IGNITION MODULE (UNDER COILS) COIL ASSEMBLIES
COMPUTER WHITE
A
CYLINDER 1
LIGHT BLUE/WHITE
TACK LEAD
GRAY/RED
G
WHITE/BLACK
H
CYLINDER 2
GROUND (REF LOW)
WHITE
E F
TACH REF (REF HIGH)
BLACK/RED
D
CYLINDER 5
BYPASS
PURPLE/WHITE
C CYLINDER 4
EST
TAN/BLACK
B
J K
CYLINDER 3
L M
CYLINDER 6
PINK/BLACK
N
A B C D IGN Bⴙ DUAL CRANK SENSOR CONNECTOR
P
FIGURE 69–14 Typical wiring diagram of a V-6 waste-spark ignition system. The computer (PCM) is in control of the ignition timing based on information from various engine sensors including engine speed (RPM), MAP and engine coolant temperature (ECT). The timing signal is sent to the module through the electronic spark timing (EST) wire in this example. CYLINDERS GROUND #1 OR #3 ON COMPRESSION CYLINDERS #1 AND #3 HAVE FIRING VOLTAGES THAT RISE A NEGATIVE DIRECTION
CYLINDERS #3 AND #1 HAVE BREAKOVER VOLTAGES THAT RISE FROM BELOW GROUND TOWARD GROUND
-10KV +4KV
CYLINDERS #2 OR #4 ON WASTE
CYLINDERS #4 AND #2 HAVE BREAKOVER VOLTAGES THAT FALL FROM ABOVE GROUND TOWARD GROUND
CYLINDERS #2 AND #4 HAVE FIRING VOLTAGES THAT RISE A POSITIVE DIRECTION GROUND
8V
CSI SIGNAL
A POSITIVE GOING VOLTAGE 4V A NEGATIVE GOING VOLTAGE
5 S GROUND
FIGURE 69–15 The slight (5 microsecond) difference in the firing of the companion cylinders is enough time to allow the PCM to determine which cylinder is firing on the compression stroke. The compression sensing ignition (CSI) signal is then processed by the PCM which then determines which cylinder is on the compression stroke.
789
IGNITION SWITCH
CKP SENSOR
INTAKE CAM PHASER SOLENOID
B+
COIL-ON-PLUG (COP) COILS
PCM
EXHAUST CAM PHASER SOLENOID
INTEGRAL COIL & PLUG
CAMSHAFT POSITION (CMP) SENSOR
FIGURE 69–17 An overhead camshaft engine equipped with variable valve timing on both the intake and exhaust camshafts and the coil-on-plug ignition.
SPARK PLUG WIRE TO COMPANION CYLINDER
FIGURE 69–16 A typical coil-on-plug ignition system showing the triggering and the switching being performed by the PCM via input from the crankshaft position sensor.
SAFETY TIP Never Disconnect a Spark Plug Wire When the Engine Is Running! Ignition systems produce a high-voltage pulse necessary to ignite a lean air-fuel mixture. If you disconnect a spark plug wire when the engine is running, this high-voltage spark could cause personal injury or damage to the ignition coil and/or ignition module.
COIL
FIGURE 69–18 A Chrysler Hemi V-8 that has two spark plugs per cylinder. The coil on top of one spark plug fires that plug and, through a spark plug wire, fires a plug in the companion cylinder.
timing also can be changed (retarded or advanced) on a cylinder-bycylinder basis for maximum performance and to respond to knock sensor signals.
TYPES OF COP SYSTEMS
There are two basic types of coil-
on-plug ignition.
Two primary wires. This design uses the vehicle computer to control the firing of the ignition coil. The two wires include ignition voltage feed and the pulse ground wire, which is controlled by the PCM. The ignition control module (ICM) is located in the PCM, which handles all ignition timing and coil on-time control.
Three primary wires. This design includes an ignition module at each coil. The three wires include: Ignition voltage
Ground
Pulse from the PCM to the built-in ignition module Vehicles use a variety of coil-on-plug-type ignition systems, such as the following:
Many General Motors V-8 engines use a coil-near-plug system with individual coils and modules for each individual
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cylinder placed on the valve covers. Short secondary ignition spark plug wires are used to connect the output terminal of the ignition coil to the spark plug, which explains why this system is called a coil-near-plug system.
A combination of coil-on-plug and waste-spark systems fires a spark plug attached to the coil and uses a spark plug wire attached to the other secondary terminal of the coil to fire another spark plug of the companion cylinder. This type of system is used in some Chrysler Hemi V-8 and Toyota V-6 engines. SEE FIGURE 69–18.
Most new engines use coil-over-plug-type ignition systems. Each coil is controlled by the PCM, which can vary the ignition timing separately for each cylinder based on signals the PCM receives from the knock sensor(s). For example, if the knock sensor detects that a spark knock has occurred after firing cylinder 3, then the PCM will continue to monitor cylinder 3 and retard timing on just this one cylinder if necessary to prevent engine damaging detonation.
ION-SENSING IGNITION
In an ion-sensing ignition system, the spark plug itself becomes a sensor. An ion-sensing ignition uses
SPARK EVENT - SPARK CURRENT FLOW
EXHAUST MANIFOLD
B+
CHARGED TO 80 VOLTS
D1 D2
C1 R1 ION SIGNAL R2
SPARK
KNOCK SENSOR
ISIM COMPONENTS ADDED TO SECONDARY CIRCUIT
FIGURE 69–20 A typical knock sensor on the side of the block. Some are located in the “V” of a V-type engine and are not noticeable until the intake manifold has been removed.
MEASUREMENT PERIOD - ION CURRENT FLOW
Ion-sensing ignition systems still function the same as conventional coil-on-plug designs, but the engine does not need to be equipped with a camshaft position sensor for misfire detection or a knock sensor, because both of these faults are achieved using the electronics inside the ignition control circuits.
B+
DISCHARGING 80 VOLTS
KNOCK SENSORS D1 D2 ION FLOW
C1 R1 ION SIGNAL R2
ISIM COMPONENTS ADDED TO SECONDARY CIRCUIT
FIGURE 69–19 A DC voltage is applied across the spark plug gap after the plug fires and the circuit can determine if the correct air-fuel ratio was present in the cylinder and if knock occurred. The applied voltage for ion sensing does not jump the spark plug gap but rather determines the conductivity of the ionized gases left over from the combustion process.
a coil-on-plug design where the ignition control module (ICM) applies a DC voltage across the spark plug gap after the ignition event to sense the ionized gases (called plasma) inside the cylinder. Ion-sensing ignition is used in the General Motors EcoTec 4-cylinder engines. SEE FIGURE 69–19. The secondary coil discharge voltage (10 to 15 kV) is electrically isolated from the ion-sensing circuit. The combustion flame is ionized and will conduct some electricity, which can be accurately measured at the spark plug gap. The purpose of this circuit includes:
Misfire detection (required by OBD-II regulations)
Knock detection (eliminates the need for a knock sensor)
Ignition timing control (to achieve the best spark timing for maximum power with lowest exhaust emissions)
Exhaust gas recirculation (EGR) control
Air-fuel ratio control on an individual cylinder basis
PURPOSE AND FUNCTION Knock sensors (KS) are used to detect abnormal combustion, often called ping, spark knock, or detonation. Whenever abnormal combustion occurs, a rapid pressure increase occurs in the cylinder, creating a vibration in the engine block. It is this vibration that is detected by the knock sensor. The signal from the knock sensor is used by the PCM to retard the ignition timing until the knock is eliminated, thereby reducing the damaging effects of the abnormal combustion on pistons and other engine parts. Inside the knock sensor is a piezoelectric element which is a type of crystal that produces a voltage when pressure or a vibration is applied to the unit. The knock sensor is tuned to the engine knock frequency, in a range from 5 to 10 kHz depending on the engine design. The voltage signal from the knock sensor is sent to the PCM, which then retards the ignition timing until the knocking stops. SEE FIGURE 69–20. DIAGNOSING THE KNOCK SENSOR If a knock sensor diagnostic trouble code (DTC) is present, follow the specified testing procedure in the service information. A scan tool can be used to check the operation of the knock sensor, using the following procedure. STEP 1
Start the engine and connect a scan tool to monitor ignition timing and/or knock sensor activity.
STEP 2
Create a simulated engine knocking sound by tapping on the engine block or cylinder head with a soft faced mallet or small ball peen hammer.
STEP 3
Observe the scan tool display. The vibration from the tapping should have been interpreted by the knock sensor as a knock, resulting in a knock sensor signal and a reduction in the spark advance.
A knock sensor also can be tested using a digital storage oscilloscope. SEE FIGURE 69–21.
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A 50V AC 1:1 PROBE B 200mV OFF 1:1 PROBE 500uS / DIV SINGLE TRIG:A -2DIV
A
A
ZOOM HOLD SINGLE FREE CAPTURE MIN MAX TRIGGER RECURRENT RUN 10 20 DIV ON A AT 50%
FIGURE 69–21 A typical waveform from a knock sensor during a spark knock event. This signal is sent to the computer which in turn retards the ignition timing. This timing retard is accomplished by an output command from the computer to either a spark advance control unit or directly to the ignition module.
?
FIGURE 69–22 A SPOUT connector on a Ford that is equipped with a distributor ignition. This connector has to be disconnected to separate the PCM in order to set base ignition timing.
and locations of the sensors for the engine being serviced. Always tighten the knock sensor using a torque wrench and tighten to the specified torque to avoid causing damage to the piezoelectric element inside the sensor.
REAL WORLD FIX
The Low Power Toyota A technician talked about the driver of a Toyota who complained about poor performance and low fuel economy. The technician checked everything, and even replaced all secondary ignition components. Then the technician connected a scan tool and noticed that the knock sensor was commanding the timing to be retarded. Careful visual inspection revealed a “chunk” missing from the serpentine belt, causing a “noise” similar to a spark knock. Apparently the knock sensor was “hearing” the accessory drive belt noise and kept retarding the ignition timing. After replacing the accessory drive belt, a test drive confirmed that normal engine power was restored. Other items that can fool the knock sensor to retard the ignition timing include: • Loose valve lifter adjustment • Engine knocks • Loose accessory brackets such as the air-conditioning compressor, power steering pumps, or alternator.
NOTE: Some engine computers are programmed to ignore knock sensor signals when the engine is at idle speed, to avoid having the noise from a loose accessory drive belt or other accessory interpreted as engine knock. Always follow the vehicle manufacturer’s recommended testing procedure.
REPLACING A KNOCK SENSOR
If replacing a knock sensor, be sure to purchase the exact replacement needed, because they often look the same, but the frequency range can vary according to engine design and location on the engine. Many engines also use two knock sensors, so check service information for exact details
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IGNITION CONTROL CIRCUITS TERMINOLOGY Ignition control (IC) is the OBD-II terminology for the output signal from the PCM to the ignition system that controls engine timing. Previously, each manufacturer used a different term to describe this signal. For instance, Ford referred to this signal as spark output (SPOUT) and General Motors referred to this signal as electronic spark timing (EST). This signal is now referred to as the ignition control (IC) signal. The ignition control signal is usually a digital output that is sent to the ignition system as a timing signal. If the ignition system is equipped with an ignition module, then this signal is used by the ignition module to vary the timing as engine speed and load change. If the PCM directly controls the coils, such as most coil-on-plug ignition systems, then this IC signal directly controls the coil primary and there is a separate IC signal for each ignition coil. The IC signal controls the time that the coil fires and it can also either advance or retard the ignition timing. On many systems, this signal controls the duration of the primary current flow in the coil, referred to as the dwell. SEE FIGURE 69–22. BYPASS IGNITION CONTROL SYSTEM
With bypass ignition control, the engine starts using the ignition module for timing control and then switches to the PCM for timing control after the engine starts. A bypass ignition is commonly used on General Motors engines equipped with distributor ignition (DI), as well as those equipped with waste-spark ignition. The bypass circuit includes four wires.
The tach reference (purple/white) wire comes from the ignition control (IC) module and is used by the PCM as engine speed information. The ground (black/white) wire is used to ensure that both the PCM and the ignition control module share the same ground.
The bypass (tan/black) wire is used to conduct a 5 volt DC signal from the PCM to the ignition control module to switch the timing control from the module to the PCM.
UP-INTEGRATED IGNITION CONTROL
NOTE: It is this bypass wire that is disconnected before the ignition timing can be set on many General Motors engines equipped with a distributor ignition.
The EST (ignition control) (white) wire is the ignition timing control signal from the PCM to the ignition control module.
Most coil-on-plug and many waste-spark-type ignition systems use the PCM for ignition timing control. This type of ignition control is called up-integrated ignition because all timing functions are interpreted in the PCM, rather than being split between the ignition control module and the PCM. The ignition module, if even used, contains only the power transistor for coil switching. The signal as to when the coil fires is determined and controlled from the PCM. Unlike a bypass ignition control circuit, it is not possible to separate the PCM from the ignition coil control to help isolate a fault.
REVIEW QUESTIONS 1. How can 12 volts from a battery be changed to 40,000 volts for ignition?
3. How does a Hall-effect sensor work? 4. How does a waste-spark ignition system work?
2. How does a magnetic sensor work?
CHAPTER QUIZ 1. The primary (low-voltage) ignition system must be working correctly before any spark occurs from a coil. Which component is not in the primary ignition circuit? a. Spark plug wiring b. Ignition module (igniter) c. Pickup coil (pulse generator) d. Ignition switch 2. The ignition module has direct control over the firing of the coil(s) of an EI system. Which component(s) triggers (controls) the module? a. Pickup coil b. Computer c. Crankshaft sensor d. All of the above 3. Distributor ignition systems ______________. a. Hall-effect sensor b. Magnetic sensor c. Spark sensor d. Either a or b
can
be
triggered
by
a
4. A compression-sensing ignition system uses a ______________type ignition. a. Distributor b. Coil-on-plug c. Waste-spark d. All of the above 5. Coil polarity is determined by the ______________. a. Direction of rotation of the coil windings b. Turns ratio c. Direction of laminations d. Saturation direction
7. The pulse generator ______________. a. Fires the spark plug directly b. Signals the electronic control unit (module) c. Signals the computer that fires the spark plug directly d. Is used as a tachometer reference signal by the computer and has no other function 8. Two technicians are discussing distributor ignition. Technician A says that the pickup coil or optical sensor in the distributor is used to pulse the ignition module (igniter). Technician B says that some distributor ignition systems use an optical sensor. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B 9. A waste-spark-type ignition system fires ______________. a. Two spark plugs at the same time b. One spark plug with reverse polarity c. One spark plug with straight polarity d. All of the above 10. Technician A says that a two-wire COP system uses the PCM to trigger the coil. Technician B says that a three-wire COP system has an ICM built into the coil assembly. Which technician is correct? a. Technician A only b. Technician B only c. Both Technicians A and B d. Neither Technician A nor B
6. How does a waste-spark ignition system fire the spark plugs? a. The polarity reverses at each firing (flip flops). b. The same plug always is fired straight or reverse polarity c. The waste spark is sent to the cylinder next to the cylinder being fired. d. Both a and c
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70
IGNITION SYSTEM DIAGNOSIS AND SERVICE
OBJECTIVES: After studying Chapter 70, the reader will be able to: • Prepare for ASE Engine Performance (A8) certification test content area “B” (Ignition System Diagnosis and Repair). • Describe the procedure used to check for spark. • Discuss what to inspect and look for during a visual inspection of the ignition system. • Explain how to test pickup coils, ignition coils, and spark plug wires. • Discuss how to current ramp ignition coils using a low ampere current clamp and a scope. • Describe how to test the ignition system using an oscilloscope. KEY TERMS: Burn kV 809 • Charging rise time 796 • Firing line 807 • Firing order 805 • Ignition timing 804 • Iridium spark plugs 802 • Millisecond (ms) sweep 809 • Module current limits 796 • Platinum spark plugs 802 • Spark line 808 • Spark tester 794
CHECKING FOR SPARK
Typical causes of a no-spark (intermittent spark) condition include the following: 1. Weak ignition coil
SPARK TESTER
In the event of a no-start condition, the first step should be to check for secondary voltage out of the ignition coil or to the spark plugs. If the engine is equipped with a separate ignition coil, remove the coil wire from the center of the distributor cap, install a spark tester, and crank the engine. See the Tech Tip, “Always Use a Spark Tester.” A good coil and ignition system should produce a blue spark at the spark tester. SEE FIGURES 70–1 AND 70–2. If the ignition system being tested does not have a separate ignition coil, disconnect any spark plug wire from a spark plug and, while cranking the engine, test for spark available at the spark plug wire, again using a spark tester.
2. Low or no voltage to the primary (positive) side of the coil 3. High resistances or open coil wire, or spark plug wire 4. Negative side of the coil not being pulsed by the ignition module 5. Defective pickup coil or crankshaft position sensor 6. Defective ignition control module (ICM) 7. Defective main relay (can be labeled main, EFI, ASD [Chrysler products], or EEC [Ford vehicles] relay) The triggering sensor has to work to create a spark from the ignition coil(s). If a no-spark condition occurs, then check for triggering by using a scan tool and check for engine RPM while cranking the engine.
NOTE: An intermittent spark should be considered a nospark condition.
FIGURE 70–1 A spark tester looks like a regular spark plug with an alligator clip attached to the shell. This tester has a specified gap that requires at least 25,000 volts (25 kV) to fire.
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FIGURE 70–2 A close-up showing the recessed center electrode on a spark tester. It is recessed 3/8 in. into the shell and the spark must then jump another 3/8 in. to the shell for a total gap of 3/4 in.
If the engine speed (RPM) shows zero or almost zero while cranking, the most likely cause is a defective triggering sensor or sensor circuit fault.
If the engine speed (RPM) is shown on the scan tool while cranking the engine, then the triggering sensor is working (in most cases).
Check service information for the exact procedure to follow for testing triggering sensors.
To test the secondary coil winding resistance, follow these steps. STEP 1
Set the meter to read kilohms (kΩ).
STEP 2
Measure the resistance either between the primary terminal and the secondary coil tower or between the secondary towers. The normal resistance of most coils ranges between 6,000 and 30,000 ohms.
Check service information for the exact procedures and specifications.
CURRENT RAMPING IGNITION COILS
IGNITION COIL TESTING IGNITION COIL TESTING USING AN OHMMETER If an ignition coil is suspected of being defective, a simple ohmmeter check can be performed to test the resistance of the primary and secondary winding inside the coil. For accurate resistance measurements, the wiring to the coil should be removed before testing. To test the primary coil winding resistance, take the following steps. SEE FIGURE 70–3. STEP 1
Set the meter to read low ohms.
STEP 2
Measure the resistance between the positive terminal and the negative terminal of the ignition coil. Most coils will give a reading between 0.5 and 3 ohms. Check the manufacturer’s specifications for the exact resistance values.
DIGITAL MULTIMETER RECORD
4
MAX MIN
6
% HZ
0 1 2 3 4 5 6 7 8
9 0
MIN MAX
HZ
mV
A
V
A
2
mA A
V
mA A
COM
V
Testing an ignition coil for resistance does not always find a coil problem that occurs under actual heat and loads. However, by using a digital storage oscilloscope and a low-current probe, the ignition system can be checked for module current limits and the charging rise time. Ignition coil operation begins with the ignition control module (ICM) completing the primary circuit through the ignition coil winding. The module allows primary current to ramp upward (primary charging time) to a preset limit. Once ramped to the preset limit, the coil remains on for a set period of time (primary saturation), known as the dwell period. Coil current is then turned off (open circuit) allowing the magnetic field built up through the dwell cycle to collapse inward, cutting across many turns of secondary coil windings, inducing a higher output voltage to fire the coil. The ignition systems used today must provide voltages of at least 25,000 volts and maintain spark duration of over 2 ms to assure good ignition over extended service intervals.
1. INSERT TEST LEADS IN THE INPUT TERMINALS SHOWN. 2. TURN THE ROTARY SWITCH TO Ω. 3. TOUCH THE PROBES AS SHOWN TO MEASURE RESISTANCE IN PRIMARY WINDINGS. 4. OBSERVE DISPLAY. RESISTANCE SHOULD BE LESS THAN A FEW OHMS. 5. TOUCH PROBES AS SHOWN TO MEASURE RESISTANCE IN SECONDARY WINDINGS. 6. OBSERVE DISPLAY. RESISTANCE SHOULD TYPICALLY BE IN THE 10 KΩ RANGE.
1
5
3
FIGURE 70–3 Checking an ignition coil using a multimeter set to read ohms.
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PRIMARY CHARGING TIME PRIMARY SATURATION COIL PRIMARY CURRENT TURNS ON
COIL PRIMARY TURNS OFF AND THE COIL FIRES
COIL PRIMARY CURRENT DWELL
DWELL
DWELL
FIGURE 70–5 A waveform showing the primary current flow through the primary windings of an ignition coil.
FIGURE 70–4 If the coil is working, the end of the magnetic pickup tool will move with the changes in the magnetic field around the coil with the engine running.
operation of the primary current control is a precise element in total ignition function and output. SEE FIGURE 70–5.
CURRENT RAMP TEST PROCEDURE
To perform a current ramp test of the ignition coil(s), take the following steps. STEP 1
TECH TIP Always Use a Spark Tester A spark tester looks like a spark plug except it has a recessed center electrode and no side electrode. The tester commonly has an alligator clip attached to the shell so that it can be clamped on a good ground connection on the engine. A good ignition system should be able to cause a spark to jump this wide gap at atmospheric pressure. Without a spark tester, a technician might assume that the ignition system is okay, because it can spark across a normal, grounded spark plug. The voltage required to fire a standard spark plug when it is out of the engine and not under pressure is about 3,000 volts or less. An electronic ignition spark tester requires a minimum of 25,000 volts to jump the 3/4 in. gap. Therefore, never assume that the ignition system is okay because it fires a spark plug—always use a spark tester. Remember that an intermittent spark across a spark tester should be interpreted as a no-spark condition.
TECH TIP The Magnetic Pickup Tool Test All ignition coils are pulsed on and off by the ignition control module or PCM. When the coil charges and discharges, the magnetic field around the coil changes. This pulsing of the coil can be observed by holding the magnetic end of a pickup tool near an operating ignition coil. The magnet at the end of the pickup tool will move as the magnetic field around the coil changes. SEE FIGURE 70–4.
Using the digital storage oscilloscope and a current probe, a quick check can be made of the overall primary condition of the two most important parameters of the ignition circuit, the module current limits and the charging rise time of the circuit. Actual circuit
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Every ignition system has a power feed circuit to the ignition coil(s). To perform current probe testing on the system, first locate the feed wire and make it current probe accessible. SEE FIGURE 70–6. This will serve as a common point on all ignition systems and include both the DI and EI units.
STEP 2
Set up the scope to read approximately 100 mV per division and 2 ms per division. This may be adjusted to suit the waveform, but will give an initial reference point. SEE CHART 70–1. A good current ramp waveform is shown in FIGURE 70–7. Examples of some faults that a current waveform can detect are shown in FIGURE 70–8.
IGNITION SENSOR TESTING MAGNETIC SENSOR TESTING Magnetic sensors are found in pickup coils, located under the distributor cap on many distributor ignition (DI) equipped engines and in crankshaft position (CKP) sensors. If defective, they can cause a no-spark condition. Magnetic sensors must generate an AC voltage pulse to the ignition control module (ICM) so that the module can pulse the ignition coil. A pickup coil or magnetic sensor contains a coil of wire, and the resistance of this coil should be within the range specified by the manufacturer. Common tests for pickup coils and magnetic crankshaft position (CKP) sensors include:
Resistance. The resistance is usually between 150 and 1,500 ohms (check service information for exact specifications). SEE FIGURE 70–9.
Short to ground. Ensure that the coil windings are insulated from ground by checking for continuity using an ohmmeter. With one ohmmeter lead attached to ground, touch the other lead of the ohmmeter to either of the two pickup coil terminals. The ohmmeter should read OL (over limit or infinity) with the ohmmeter set on the highest ohms scale. If the ohmmeter shows a reading of any resistance or even zero, then the pickup coil is shorted to ground and should be
SPARK PLUGS
BATTERY VOLTAGE ⴙ12 VOLTS
PRIMARY IGNITION TRIGGER SOURCE FROM IGNITION MODULE CONNECT CURRENT CLAMP HERE
SENSOR GROUND
FIGURE 70–6 Schematic of a typical waste-spark ignition system showing the location for the power feed and grounds. (Courtesy of Fluke Corporation)
OBSERVED CURRENT RAMP TIMES GM electronic (DI) systems
3.6 ms
GM late 1996 and up (DI) systems
2.5 ms
GM electronic (EI) systems
2.6 ms
Ford electronic (DI) systems
3.6 ms
Ford electronic (EI) systems
2.6 ms
Chrysler electronic (DI) systems
3.8 ms
Chrysler electronic (EI) systems
2.6 ms
CHART 70–1 The ignition coil ramp times vary according to the type of ignition system.
AN OPEN COIL PRIMARY WINDING WILL BE IDENTIFIED BY A MISSING PULSE IN THE CURRENT PATTERN. (a)
GOOD COIL PATTERN
FIGURE 70–7 An example of a good coil current flow waveform pattern. Note the regular shape of the rise time and slope. Duration of the waveform may change as the module adjusts the dwell. The dwell is usually increased as the engine speed is increased. (Courtesy of Fluke Corporation) replaced. If the pickup coil resistance is not within the specified range or if it has continuity to ground, then replace the pickup coil assembly.
AC voltage output. The pickup coil also can be tested for proper voltage output. During cranking, most pickup coils should produce a minimum of 0.25 volt AC.
A SHORTENED COIL WILL HAVE A SQUARE SHAPED CURRENT RAMP (DUE TO REDUCED PRIMARY COIL RESISTANCE.) (b)
FIGURE 70–8 (a) A waveform pattern showing an open in the coil primary. (b) A shorted coil pattern waveform. (Courtesy of Fluke Corporation)
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Scope testing. A pickup coil can also be checked on a scope. The waveform created is an analog (continuously variable) and is produced by the strengthening and weakening of the magnetic field as the points of the timer core rotate past the points of the pole pieces. SEE FIGURE 70–10.
REAL WORLD FIX The Weird Running Chevrolet Truck An older Chevrolet pickup truck equipped with a V-8 engine was towed into a shop because it would not start. A quick check of the ignition system showed that the pickup coil had a broken wire below it and the ignition control module. The distributor was removed from the engine and the distributor shaft was removed, cleaned, and a replacement pickup coil was installed. The engine started but ran rough and hesitated when the accelerator pedal was depressed. After an hour of troubleshooting, a careful inspection of the new pickup coil showed that the time core had six instead of eight points, meaning that the new pickup coil was meant for a V-6 instead of a V-8 engine. Replacing the pickup coil again solved the problem.
The changing magnetic field is sent to the ICM where it turns off the current through the primary winding of the ignition coil. SEE FIGURE 70–11.
REAL WORLD FIX The Hard-to-Start Chevrolet HHR FIGURE 70–9 Measuring the resistance of an HEI pickup coil using a digital multimeter set to the ohms position. The reading on the face of the meter is 0.796 kΩ or 796 ohms in the middle of the 500 to 1,500 ohm specifications. STRENGTHENING FIELD
The owner of a 2008 Chevrolet HHR complained that the engine was hard to start and required a long period of cranking. Once the engine started, it ran great all day. A P0336 crankshaft position (CKP) sensor fault code was stored. SEE FIGURE 70–12. The CKP sensor had been replaced several times before and the sensor output was scope tested yet everything appeared to be normal. Then one time when the engine started, the technician noticed that while it was running the engine speed (RPM) displayed on the Tech 2 scan tool was zero. SEE FIGURE 70–13. After replacing the crankshaft position sensor again and checking the wiring, the technician looked at the reluctor wheel using a boroscope. Some blades of the reluctor wheel were bent. The cause was likely when the first sensor failed and possibly damaged the reluctor. As a result of the testing, the local Chevrolet dealer replaced the crankshaft under warranty. SEE FIGURE 70–14.
WEAKENING FIELD
POLE PIECE
TIMER CORE
TIMER CORE AIR GAP
(a)
REFERENCE VOLTAGE
0
ENGINE ROTATION
CURRENT LIMIT
(b)
DWELL
ENGINE ROTATION
PICKUP OUTPUT VOLTAGE
LOW-SPEED
COIL CURRENT
COIL CURRENT
PICKUP OUTPUT VOLTAGE
FIGURE 70–10 A typical pickup coil showing how the waveform is created as the timer core rotates inside the pole piece.
HIGH-SPEED REFERENCE VOLTAGE
0
(c)
ENGINE ROTATION CURRENT LIMIT
DWELL
(d)
ENGINE ROTATION
FIGURE 70–11 (a) A voltage waveform of a pickup coil at low engine speed. (b) A current waveform of the current through the primary windings of the ignition coil at low engine speed. (c) A voltage waveform of a pickup coil at high speed. (d) A current waveform through the primary winding of the ignition coil at high engine speed.
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FIGURE 70–12 A diagnostic trouble code P0336 was displayed on a Tech 2 scan tool as the only code.
FIGURE 70–14 The old crankshaft showing the reluctor notches. The damage was not visible, but the engine started each time after the crankshaft was replaced.
AUTOMOTIVE SCOPMETER HOLD
FIGURE 70–13 The engine started and was running, but the Tech 2 displayed zero RPM.
HALL-EFFECT SENSOR TESTING A Hall effect sensor uses a semiconductor chip to produce an on and off signal when exposed to a magnetic field. Using a digital voltmeter, check for the following:
Power and ground to the sensor
Changing voltage (pulsed on and off or digital DC voltage) when the engine is being cranked (The usual voltage range is 0 to 5 volts, or 0 to 8 volts depending on the sensors and the application.)
Another test is to use an oscilloscope and observe the waveform. SEE FIGURE 70–15.
4.72 V 127 HZ 42.0 % 3.06 MS
PEAK - PEAK
AUTO
FREQUENCY
25 20 15 10
DUTY CYCLE
5 0 -5
PULSE WIDTH
VEHICLE DATA
PRADE SINGLE
RANGE
6V
4
MENU
RECORD
2 SAVE RECALL
AUTO RANGE
0 -2V 2MS/DIV
HALL-EFFECT SENSOR
KEYS RANGE
FIGURE 70–15 The connection required to test a Hall-effect sensor. A typical waveform from a Hall-effect sensor is a digital square wave. Check service information for the signal wire location.
OPTICAL SENSOR TESTING
Optical sensors will not operate if dirty or covered in oil. Perform a thorough visual inspection and look for an oil leak that could cause dirty oil to get on the LED or phototransistor. Also be sure that the light shield is securely fastened and that the seal is lightproof. An optical sensor also can be checked using an oscilloscope. SEE FIGURE 70–16. Because of the speed of the engine and the number of slits in the optical sensor disk, a scope is one of the only tools that can capture useful information. For example, a Nissan has 360 slits and if it is running at 2,000 RPM, a signal is generated 720,000 times per minute or 12,000 times per second.
SPARK PLUG WIRE INSPECTION VISUAL INSPECTION Spark plug wires should be visually inspected for cuts or defective insulation. Faulty spark plug wire insulation can cause hard starting or no starting in rainy or damp weather conditions. When removing a spark plug wire, be sure to rotate the boot of the wire at the plug before pulling it off the spark plug. This
I G N I T I O N SYST E M D I AG N O SI S A N D S ERVIC E
799
A 2V DC 1:1 PROBE B 200mV OFF 1:1 PROBE 10ms / TRIG:A -1 DIV
A 2V DC 1:1 PROBE B 200mV OFF 1:1 PROBE 10ms / TRIG:A -1 DIV
A A
A A
ZOOM
ZOOM
HOLD
HOLD B SINGLE FREE CAPTURE MIN MAX TRIGGER RECURRENT RUN 10 20 DIV ON A AT 50%
SINGLE FREE CAPTURE MIN MAX TRIGGER RECURRENT RUN 10 20 DIV ON A AT 50%
(b)
(a)
FIGURE 70–16 (a) The low-resolution signal has the same number of pulses as the engine has cylinders. (b) A dual trace pattern showing both the low-resolution and the high-resolution signals that usually represent 1 degree of rotation.
PRIMARY COIL WINDINGS STEEL CORE
SECONDARY COIL WINDINGS
TRACKING TO STEEL CORE
COIL EPOXY CASE AIR GAP
FIGURE 70–17 A track inside an ignition coil is not a short, but a low-resistance path or hole that has been burned through from the secondary wiring to the steel core.
FIGURE 70–18 Corroded terminals on a waste-spark coil can cause misfire diagnostic trouble codes to be set.
TECH TIP TECH TIP Bad Wire? Replace the Coil! When performing engine testing (such as a compression test), always ground the coil wire or disable the primary ignition circuit by removing the ignition fuse. If the spark cannot spark to ground, the coil energy can (and usually does) arc inside the coil itself, creating a low-resistance path to the primary windings or the steel laminations of the coil. SEE FIGURE 70–17. This low-resistance path is called a track and could cause an engine miss under load even though all of the remaining component parts of the ignition system are functioning correctly. Often these tracks do not show up on any coil test, including most scopes. Because the track is a lower resistance path to ground than normal, it requires that the ignition system be put under a load for it to be detected; and even then, the problem such as an engine misfire may be intermittent.
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Spark Plug Wire Pliers Are a Good Investment Spark plug wires are often difficult to remove. Using good-quality spark plug wire pliers, as shown in FIGURE 70–18, saves time and reduces the chance of harming the wire during removal.
will help prevent damaging the wire as many wires are stuck to the spark plug and are often difficult to remove. Make a thorough visual inspection of the following items.
Check all spark plug wires for proper routing. All plug wires should be in the factory wiring separators and be clear of any metallic object that could damage the insulation and cause a short-to-ground fault.
Check that all spark plug wires are securely attached to the spark plugs and to the distributor cap or ignition coil(s).
FIGURE 70–19 This spark plug boot on an overhead camshaft engine has been arcing to the valve cover causing a misfire to occur.
FIGURE 70–22 A water spray bottle is an excellent diagnostic tool to help find an intermittent engine misfire caused by a break in a secondary ignition circuit component.
TECH TIP
FIGURE 70–20 Measuring the resistance of a spark plug wire with a multimeter set to the ohms position. The reading of 16.03 kΩ (16.03 ohms) is okay because the wire is about 2 ft long. Maximum allowable resistance for a spark plug wire this long would be 20 kΩ (20,000 ohms).
Use a Water Spray Bottle to Check for Bad Spark Plug Wires For intermittent problems, use a spray bottle to apply a water mist to the spark plugs, distributor cap, and spark plug wires. SEE FIGURE 70–22. With the engine running, the water may cause an arc through any weak insulating materials and cause the engine to miss or stall. NOTE: Adding a little salt or liquid soap to the water makes the water more conductive and also makes it easier to find those hard-to-diagnose intermittent ignition faults.
SPARK PLUGS FIGURE 70–21 Spark plug wire boot pliers are a handy addition to any tool box.
Check that all spark plug wires are clean and free from excessive dirt or oil. Check that all protective covers normally covering the coil and/or distributor cap are in place and not damaged.
Carefully check the cap and distributor rotor for faults or coil secondary terminal on waste spark coils. SEE FIGURE 70–19.
SPARK PLUG CONSTRUCTION
Spark plugs are manufactured from ceramic insulators inside a steel shell. The threads of the shell are rolled and a seat is formed to create a gas-tight seal with the cylinder head. SEE FIGURE 70–23. Physical differences in spark plugs include the following:
Reach. The reach is the length of the threaded part of the plug.
Heat range. The heat range of the spark plug refers to how rapidly the heat created at the tip is transferred to the cylinder head. A plug with a long ceramic insulator path will run hotter at the tip than a spark plug that has a shorter path because the heat must travel farther. SEE FIGURE 70–24.
Type of seat. Some spark plugs use a gasket and others rely on a tapered seat to seal.
Visually check the wires and boots for damage. SEE FIGURE 70–20.
OHMMETER TESTING
Check all spark plug wires with an ohmmeter for proper resistance. Good spark plug wires should measure less than 10,000 ohms per foot of length. SEE FIGURE 70–21.
I G N I T I O N SYST E M D I AG N O SI S A N D S ERVIC E
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CERAMIC INSULATOR
METAL SHELL
METAL SHELL INSULATION
THREADS
SIDE ELECTRODE
FIGURE 70–25 When removing spark plugs, it is wise to arrange them so that they can be compared and any problem can be identified with a particular cylinder.
CENTER ELECTRODE
FIGURE 70–23 Parts of a spark plug.
FIGURE 70–26 A spark plug thread chaser is a low-cost tool that hopefully will not be used often, but is necessary in order to clean the threads before installing new spark plugs.
FAST HEAT TRANSFER
MEDIUM HEAT TRANSFER
COLD PLUG
SLOW HEAT TRANSFER HOT PLUG
FIGURE 70–24 The heat range of a spark plug is determined by the distance the heat flows from the tip to the cylinder head.
RESISTOR SPARK PLUGS
Most spark plugs include a resistor in the center electrode, to reduce electromagnetic noise or radiation from the ignition system. The closer the resistor is to the actual spark or arc, the more effective it becomes. The value of the resistor is usually between 2,500 and 7,500 ohms.
Nonplatinum spark plugs have a service life of over 20,000 miles (32,000 km).
Platinum-tipped original equipment spark plugs have a typical service life of 60,000 to 100,000 miles (100,000 to 160,000 km) or longer.
Used Platinum-tipped spark plugs should not be regapped! Using a gapping tool can break the platinum after it has been used in an engine. Check service information regarding the recommended type of spark plugs and the specified service procedures.
SPARK PLUG SERVICE STEP 1
Check service information. Check for the exact spark plug to use and the specified instructions and/or technical service bulletins that affect the part number of plug to be used or a revised replacement procedure.
STEP 2
Allow the engine to cool before removing spark plugs. This step is especially critical on engines with aluminum cylinder heads.
STEP 3
Use compressed air or a brush to remove dirt from around the spark plug before removal. This step helps prevent dirt from getting into the cylinder of an engine while removing a spark plug.
STEP 4
Check the spark plug gap and correct as needed. Be careful not to damage the tip on the center electrode if adjusting a platinum or iridium type of spark plug.
STEP 5
Install the spark plugs. Be sure the threads are clean by using a thread chaser. Then install the spark plug by hand, then using the proper spark plug socket and a torque wrench, tighten the plugs to factory specifications.
PLATINUM SPARK PLUGS
Platinum spark plugs have a small amount of the precious metal platinum included onto the end of the center electrode, as well as on the ground or side electrode. Platinum is a gray-white metal that does not react with oxygen and, therefore, will not erode away as can occur with conventional nickel alloy spark plug electrodes. Platinum is also used as a catalyst in catalytic converters where it is able to start a chemical reaction without itself being consumed.
IRIDIUM SPARK PLUGS
Iridium is a white precious metal and is the most corrosion-resistant metal known. Most iridium spark plugs use a small amount of iridium welded onto the tip of a small center electrode 0.0015 to 0.002 in. (0.4 to 0.6 mm) in diameter. The small diameter reduces the voltage required to jump the gap between the center and the side electrode, thereby reducing possible misfires. The ground or side electrode is usually tipped with platinum to help reduce electrode gap wear. Spark plugs should be inspected when an engine performance problem occurs and should be replaced at specified intervals to ensure proper ignition system performance.
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When replacing spark plugs, perform
the following steps.
SEE FIGURES 70–25 AND 70–26.
FIGURE 70–27 A normally worn spark plug that uses a tapered platinum-tipped center electrode.
FIGURE 70–28 Spark plug removed from an engine after a 500-mile race. Note the clipped side (ground) electrode. The electrode design and narrow (0.025 in.) gap are used to ensure that a spark occurs during extremely high engine speed operation.
FIGURE 70–29 Typical worn spark plug. Notice the rounded center electrode. The deposits indicate a possible coolant usage problem.
FIGURE 70–30 New spark plug that was fouled by an overly rich air-fuel mixture. The engine from which this spark plug came had a defective (stuck partially open) injector on this one cylinder only.
Spark plugs are the windows to the inside of the combustion chamber. A thorough visual inspection of the spark plugs often can lead to the root cause of an engine performance problem. Two indications on spark plugs and their possible root causes in engine performance include the following: 1. Carbon fouling. If the spark plug(s) has dry black carbon (soot), the usual causes include: Excessive idling Defective thermostat Overly rich air-fuel mixture due to a fuel system fault Weak ignition system output 2. Oil fouling. If the spark plug has wet, oily deposits with little electrode wear, oil may be getting into the combustion chamber from the following:
Worn or broken piston rings Worn valve guides Defective or missing valve stem seals
When removing spark plugs, place them in order so that they can be inspected to check for engine problems that might affect one or more cylinders. All spark plugs should be in the same condition, and the color of the center insulator should be light tan or gray. If all the spark plugs are black or dark, the engine should be checked for conditions that could cause an overly rich air-fuel mixture or possible oil burning. If only one or a few spark plugs are black, check those cylinders for proper firing (possible defective spark plug wire) or an engine condition affecting only those particular cylinders. SEE FIGURES 70–27 THROUGH 70–30. If all spark plugs are white, check for possible overadvanced ignition timing or a vacuum leak causing a lean air-fuel mixture. If only one or a few spark plugs are white, check for a vacuum leak or injector fault affecting the air-fuel mixture only to those particular cylinders.
I G N I T I O N SYST E M D I AG N O SI S A N D S ERVIC E
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TORQUE WITH TORQUE WRENCH (LB-FT)
SPARK PLUG TYPE Gasket
CAST-IRON HEAD
TORQUE WITHOUT TORQUE WRENCH (TURNS AFTER SEATED)
ALUMINUM HEAD
CAST-IRON HEAD
ALUMINUM HEAD
14 mm
26–30
18–22
1/4
1/4
18 mm
32–38
28–34
1/4
1/4
Tapered seat
14 mm
7–15
7–15
1/16 (snug)
1/16 (snug)
18 mm
15–20
15–20
1/16 (snug)
1/16 (snug)
CHART 70–2 Typical spark plug installation torque.
TECH TIP Two-Finger Trick TDC MARK
To help prevent overtightening a spark plug when a torque wrench is not available, simply use two fingers on the ratchet handle. Even the strongest service technician cannot overtighten a spark plug by using two fingers. TIMING MARK ON HARMONIC BALANCER
NOTE: The PCM “senses” rich or lean air-fuel ratios by means of input from the oxygen sensor(s). If one cylinder is lean, the PCM may make all other cylinders richer to compensate. Inspect all spark plugs for wear by first checking the condition of the center electrode. As a spark plug wears, the center electrode becomes rounded. If the center electrode is rounded, higher ignition system voltage is required to fire the spark plug. When installing spark plugs, always use the correct tightening torque to ensure proper heat transfer from the spark plug shell to the cylinder head. SEE CHART 70–2. NOTE: General Motors does not recommend the use of antiseize compound on the threads of spark plugs being installed in an aluminum cylinder head, because the spark plug will be overtightened. This excessive tightening torque places the threaded portion of the spark plug too far into the combustion chamber where carbon can accumulate and result in the spark plugs being difficult to remove. If antiseize compound is used on spark plug threads, reduce the tightening torque by 40%. Always follow the vehicle manufacturer’s recommendations.
IGNITION TIMING PURPOSE Ignition timing refers to when the spark plug fires in relation to piston position. The time when the spark occurs depends on engine speed, and therefore, it must be advanced (spark plugs fire sooner) as the engine rotates faster. The ignition process in the cylinder takes a certain amount of time, usually 30 ms (30/1,000 of a second) and remains constant regardless of engine speed. Therefore, to maintain the most efficient combustion, the ignition sequence has to occur sooner as the engine speed increases. For maximum efficiency from the expanding gases inside the combustion chamber, the burning of the air-fuel mixture should end by about 10 degrees after top dead center (ATDC). If the burning of the mixture is still occurring after that point, the expanding gases do not
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FIGURE 70–31 Ignition timing marks are found on the harmonic balancers on engines equipped with distributors that can be adjusted for timing.
exert much force on the piston because the gases are “chasing” the piston as it moves downward. Therefore, to achieve the goal of having the air-fuel mixture be completely burned by the time the piston reaches 10° after top dead center (ATDC), the spark must be advanced (occur sooner) as the engine speed increases. This timing advance is determined and controlled by the PCM on most vehicles. SEE FIGURE 70–31. If the engine is equipped with a distributor, it may or may not be possible to adjust the base or the initial timing. Check service information for details regarding the vehicle being serviced. The initial timing is usually set to fire the spark plug between zero degrees (top dead center, or TDC) or slightly before TDC (BTDC). Initial (base) ignition timing changes as mechanical wear occurs on the following:
Timing chain
Distributor gear
Camshaft drive gear
SEE FIGURE 70–32.
ADVANCE ANGLE BEFORE TDC
40°
30°
20°
10°
0° 0
INITIAL TIMING 1000
2000 3000 4000 ENGINE SPEED (RPM)
5000
FIGURE 70–33 The firing order is cast or stamped on the intake manifold of most engines that have a distributor ignition.
FIGURE 70–32 The initial (base) timing is where the spark plug fires at idle speed. The PCM then advances the timing based primarily on engine speed.
TECH TIP Two Marks Are the Key to Success When a distributor is removed from an engine, always mark where the rotor is pointing to ensure that the distributor is reinstalled in the correct position. Because of the helical cut on the distributor drive gear, the rotor rotates as the distributor is being removed from the engine. To help reinstall a distributor without problems, simply make another mark where the rotor is pointing just as the distributor is lifted out of the engine. Then to reinstall, line up the rotor to the second mark and lower the distributor into the engine. The rotor should then line up with the original mark as a double check.
FIGURE 70–34 Always take the time to install spark plug wires back into the original holding brackets (wiring combs). TECH TIP
CHECKING IGNITION TIMING To be assured of the proper ignition timing, follow the exact timing procedure indicated on the underhood vehicle emission control information (VECI) decal. If the decal is missing, check with service information for the timing procedure. NOTE: The ignition timing for waste-spark and coil-on-plug ignition systems cannot be adjusted.
FIRING ORDER Firing order is the order that the spark is distributed to the correct spark plug at the right time. The firing order of an engine is determined by crankshaft and camshaft design. The ignition firing order is determined by the location of the spark plug wires in the distributor cap of an engine equipped with a distributor and how the spark plug wires are installed on the waste-spark coils. The firing order is often cast into the intake manifold for easy reference. SEE FIGURE 70–33. NOTE: Most service manuals also show the firing order and the direction of the distributor rotor rotation, how the cylinders are numbered, and the location of the spark plug wires on the distributor cap. Firing order is also important for waste-spark-type ignition systems. The spark plug wire can often be installed on the wrong coil pack, creating a no-start condition or poor engine operation.
Route the Wires Right! High voltage is present through spark plug wires when the engine is running. Surrounding the spark plugs is a magnetic field that can affect other circuits or components of the vehicle. For example, if a spark plug wire is routed too closely to the signal wire from a mass airflow (MAF) sensor, the induced signal from the ignition wire could create a false MAF signal to the PCM. The PCM, not knowing the signal was false, would act on the MAF signal and command the appropriate amount of fuel based on the false MAF signal. To prevent any problems associated with high-voltage spark plug wires, be sure to route them the same as the original plug wires, using all factory holding brackets and wiring combs. SEE FIGURE 70–34. Most factory service manuals show the correct routing if the factory method is unknown.
DISTRIBUTOR INDEXING A few engines using a distributor also use it to house a camshaft position (CMP) sensor. One purpose of this sensor is to properly initiate the fuel-injection sequence. Some of these engines use a positive distributor position notch or clamp that allows the distributor to be placed in only one position, while others use a method of indexing to verify the distributor position. SEE FIGURE 70–35.
I G N I T I O N SYST E M D I AG N O SI S A N D S ERVIC E
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CAMSHAFT POSITION SENSOR
CRANKSHAFT POSITION SENSOR
FIGURE 70–35 The relationship between the crankshaft position (CKP) sensor and the camshaft position (CMP) sensor is affected by wear in the timing gear and/or chain.
FIGURE 70–37 A worn distributor drive gear can be the cause of an out-of-specification camshaft position (CMP) signal.
NO-START DIAGNOSIS A no-start condition (with normal engine cranking speed) can be the result of either no spark or no fuel delivery. The PCM uses the ignition primary pulses as a signal to inject fuel in a fuel-injection system. If there is no pulse, then there is no squirt of fuel. To determine exactly what is wrong, follow these steps. STEP 1
Test the output signal from the crankshaft sensor. Most engines with waste-spark or COP ignitions use a crankshaft position (CKP) sensor. These sensors are either the Hall-effect or the magnetic type. The sensors must be able to produce a variable (either analog or digital) signal. A voltmeter set to read DC volts for a Hall-effect sensor or set to read AC volts for a magnetic sensor should read a voltage across the sensor leads when the engine is being cranked. If there is no changing voltage output, replace the sensor.
STEP 2
If the sensor tests okay in step 1, check for a changing voltage signal at the ignition module.
FIGURE 70–36 A scan tool displays excessive cam retard on a Chevrolet pickup truck V-6. The cam retard value should be ⫾ 2 degrees.
NOTE: Step 2 checks the wiring between the crankshaft position (CKP) sensor and the ignition control module. STEP 3
If a distributor is not indexed correctly, the following symptoms may occur.
Surging (especially at idle speed)
Light bucking
Intermittent engine misfiring
If the ignition control module is receiving a changing signal from the crankshaft position sensor, it must be capable of switching the power to the ignition coils on and off. Remove a coil or coil package, and with the ignition switched to on (run), check for voltage at the positive terminal of the coil(s).
NOTE: This is not the same as setting the ignition timing. Indexing the distributor does not affect the ignition timing.
NOTE: Several manufacturers program the current to the coils to be turned off within several seconds of the ignition being switched to on if no pulse is received by the PCM. This circuit design helps prevent ignition coil damage in the event of a failure in the control circuit or driver error, by keeping the ignition switch on (run) without operating the starter (start position). Some Chrysler brand engines do not supply power to the positive (⫹) side of the coil through the automatic shutdown (ASD) relay until a crank pulse is received by the PCM.
Always use the factory procedure as stated in service information. Some of the methods may require a scan tool, while others require the use of a voltmeter to verify position. Jeep, late model Chrysler V-6 and V-8 engines, and some GM trucks require indexing. SEE FIGURES 70–36 AND 70–37.
CAUTION: Most ignition systems can produce 40,000 volts or more, with energy levels high enough to cause personal injury. Do not disconnect a spark plug wire while the engine is running, because it may damage the ignition system or create a shock hazard.
This will most likely occur when the vehicle is at operating temperature, and under a light load at approximately 2,000 RPM. A misindexed distributor may cause these conditions.
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20 KV
40 KV/V
15 KV
30 KV/V
TO SCOPE 4 GROUND CLAMP
1 SECONDARY PICKUP
ENGINE GROUND
ⴙ
3 PRIMARY PICKUP ⴚ
2 TRIGGER PICKUP
FIRING LINE
10 KV
20 KV/V
SPARK LINE (SPARK DURATION) NUMBER 1 SPARK PLUG
INTERMEDIATE SECTION
5 KV
0 KV 0
FIGURE 70–38 Typical engine analyzer hookup that includes a scope display. (1) Coil wire on top of the distributor cap if integral type of coil; (2) number 1 spark plug connection; (3) negative side of the ignition coil; (4) ground (negative) connection of the battery.
1 mS
2 mS
DWELL SECTION
3 mS
4 mS
10 KV/V
0 KV/V 5 mS
FIGURE 70–40 Typical secondary ignition oscilloscope pattern.
SECONDARY CONVENTIONAL (SINGLE) FIRING LINE (BEGINNING OF SPARK) POINTS CLOSE OR TRANSISTOR TURNS ON
SPARK LINE SPARK ENDS
POINTS OPEN OR TRANSISTOR TURNS OFF
GM HEI SYSTEM CONNECTION
DWELL SECTION HONDA HEI SYSTEM CONNECTION
COIL OSCILLATIONS
INTERMEDIATE SECTION FIRING SECTION
SECONDARY CONVENTIONAL (PARADE) TOYOTA HEI SYSTEM CONNECTION
FIGURE 70–39 Clip-on adapters are used with an ignition system that uses an integral ignition coil.
IGNITION SCOPE TESTING TERMINOLOGY
All ignition systems must charge and discharge an ignition coil. With the engine off, ignition scopes will display a horizontal line. With the engine running, this horizontal (zero) line is changed to a pattern that will have sections both above and below the zero line. Sections of this pattern that are above the zero line indicate that the ignition coil is discharging. Sections of the scope pattern below the zero line indicate charging of the ignition coil. The height of the scope pattern indicates voltage. The length (from left to right) of the scope pattern indicates time. SEE FIGURES 70–38 AND 70–39 for typical scope hookups.
FIRING LINES SHOULD BE EQUAL. A SHORT LINE INDICATES LOW RESISTANCE IN THE WIRE. A HIGH LINE INDICATES HIGH RESISTANCE IN THE WIRE. AVAILABLE VOLTAGE SHOULD BE ABOUT 10 KV ON A CONVENTIONAL IGNITION SYSTEM AND EVEN GREATER WITH AN ELECTRONIC SYSTEM SPARK LINES CAN BE VIEWED SIDE-BY-SIDE FOR EASE OF COMPARISON CYLINDERS ARE DISPLAYED IN FIRING ORDER
FIGURE 70–41 A single cylinder is shown at the top and a 4-cylinder engine at the bottom.
FIRING LINE The leftmost vertical (upward) line is called the firing line. The height of the firing line should be between 5,000 and 15,000 volts (5 and 15 kV) with not more than a 3 kV difference between the highest and the lowest cylinder’s firing line. SEE FIGURES 70–40 AND 70–41.
I G N I T I O N SYST E M D I AG N O SI S A N D S ERVIC E
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SPARK STARTS
SPARK ENDS
TRANSISTOR OFF COIL OSCILLATIONS TRANSISTOR ON
FIRING LINE FOR NEXT CYLINDER IN FIRING ORDER
FIGURE 70–42 Drawing shows what is occurring electrically at each part of the scope pattern.
5 KV
10 KV/V
0 KV
0 KV/V
20 KV
40 KV/V
15 KV
30 KV/V
10 KV
20 KV/V
5 KV
10 KV/V
0 KV
0 KV/V RASTER (STACKED)
FIGURE 70–44 Raster is the best scope position to view the spark lines of all the cylinders to check for differences. Most scopes display cylinder 1 at the bottom. The other cylinders are positioned by firing order above cylinder 1.
SUPERIMPOSED
FIGURE 70–43 Typical secondary ignition pattern. Note the lack of firing lines on the superimposed pattern. The height of the firing line indicates the voltage required to fire the spark plug. It requires a high voltage to make the air inside the cylinder electrically conductive (to ionize the air). One or more of the following conditions may cause higher-than-normal height firing lines. 1. Spark plug gapped too wide 2. Lean fuel mixture 3. Defective spark plug wire (excessive resistance or electrically open) If the firing lines are higher than normal for all cylinders, then possible causes include one or more of the following: 1. Worn distributor cap and/or rotor (if the vehicle is so equipped) 2. Excessive wearing of all spark plugs 3. Defective coil wire (the high voltage could still jump across the open section of the wire to fire the spark plugs)
SPARK LINE The spark line is a short horizontal line connected to the firing line. The height of the spark line represents the voltage required to maintain the spark across the spark plug after the spark has started. The height of the spark line should be one-fourth of the height of the firing line (between 1.5 and 2.5 kV). The length (from left to right) of the line represents the length of time for which the spark lasts (duration). The spark duration should be between 0.8 and 2.2 milliseconds (usually between 1.0 and 2.0 ms). The spark stops at the end (right side) of the spark line, as shown in FIGURE 70–42. INTERMEDIATE OSCILLATIONS
After the spark has stopped, some energy remains in the coil. This remaining energy dissipates in the coil windings and the entire secondary circuit. The oscillations are also called the “ringing” of the coil as it is pulsed. The secondary pattern amplifies any voltage variation occurring in the primary circuit because of the turns ratio between the primary and secondary windings of the ignition coil. A correctly operating ignition system should display five or more “bumps” (oscillations) (three or more for a GM HEI system).
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TRANSISTOR-ON POINT
After the intermediate oscillations, the coil is empty (not charged), as indicated by the scope pattern being on the zero line for a short period. When the transistor turns on in an electronic ignition system, the coil is being charged. Note that the charging of the coil occurs slowly (coil-charging oscillations) because of the inductive reactance of the coil.
DWELL SECTION Dwell is the amount of time that the current is charging the coil from the transistor-on point to the transistor-off point. The end of the dwell section marks the beginning of the next firing line. This point is called “transistor off,” and indicates that the primary current of the coil is stopped, resulting in a high-voltage spark out of the coil. PATTERN SELECTION The entire pattern is not seen on a scope. Ignition oscilloscopes use three positions to view certain sections of the basic pattern more closely. These three positions are as follows: 1. Superimposed. This superimposed position is used to look at differences in patterns between cylinders in all areas except the firing line. There are no firing lines illustrated in superimposed positions. SEE FIGURE 70–43. 2. Raster (stacked). Cylinder 1 appears at the bottom of the screen and all other cylinder patterns are displayed upward in the engine’s firing order. Use the raster (stacked) position to look at the spark line length and transistor-on point. The raster pattern shows all areas of the scope pattern except the firing lines. SEE FIGURE 70–44. 3. Display (parade). Display (parade) is the only position in which firing lines are visible and the cylinders are displayed on the screen from left to right in the engine’s firing order. This selection is used to compare the height of firing lines among all cylinders. SEE FIGURE 70–45.
READING THE SCOPE ON DISPLAY (PARADE) Start the engine and operate at approximately 1,000 RPM to ensure a smooth and accurate scope pattern. Firing lines are visible only on the display (parade) position. The firing lines should all be 5 to 15 kV in height and be within 3 kV of each other. If one or more cylinders have high firing lines, this could indicate a defective (open) spark
NORMAL SPARK LINE LENGTH (AT 700 TO 1200 RPM) 5 KV
10 KV/V
NUMBER OF CYLINDERS
MILLISECONDS
PERCENTAGE (%) OF DWELL SCALE
DEGREES
4
1–2
3–6
3–5
6
1–2
4–9
2–5
8
1–2
6–13
3–6
0 KV/V
0 KV DISPLAY (PARADE)
FIGURE 70–45 Display is the only position to view the firing lines of all cylinders. Cylinder 1 is displayed on the left (except for its firing line, which is shown on the right). The cylinders are displayed from left to right by firing order.
CHART 70–3 Converting between units is sometimes needed depending on the type of scope used. 10 KV
20 KV/V
5 KV
10 KV/V
0 KV
0 KV/V
REAL WORLD FIX A Technician’s Toughie A vehicle ran poorly, yet its scope patterns were “perfect.” Remembering that the scope indicates only that a spark has occurred (not necessarily inside the engine), the technician grounded one spark plug wire at a time using a vacuum hose and a test light. Every time a plug wire was grounded, the engine ran worse, until the last cylinder was checked. When the last spark plug wire was grounded, the engine ran the same. The technician checked the spark plug wire with an ohmmeter; it tested within specifications (less than 10,000 ohms per foot of length). The technician also removed and inspected the spark plug. The spark plug looked normal. The spark plug was reinstalled and the engine tested again. The test had the same results as before—the engine seemed to be running on seven cylinders, yet the scope pattern was perfect. The technician then replaced the spark plug for the affected cylinder. The engine ran correctly. Very close examination of the spark plug showed a thin crack between the wire terminal and the shell of the plug. Why didn’t the cracked plug show on the scope? The scope simply indicated that a spark had occurred. The scope cannot distinguish between a spark inside and outside the engine. In this case, the voltage required to travel through the spark plug crack to ground was about the same voltage required to jump the spark plug electrodes inside the engine. The spark that occurred across the cracked spark plug, however, may have been visible at night with the engine running.
FIGURE 70–46 A downward-sloping spark line usually indicates high secondary ignition system resistance or an excessively rich air-fuel mixture. gaps of the rotor and the spark plug, there may not be enough energy remaining to create a spark duration long enough to completely burn the air-fuel mixture. Many scopes are equipped with a millisecond (ms) sweep. This means that the scope will sweep only that portion of the pattern that can be shown during a 5 ms or 25 ms setting. Following are guidelines for spark line length.
0.8 ms: too short
1.5 ms: average
2.2 ms: too long If the spark line is too short, possible causes include the following:
1. Spark plug(s) gapped too widely 2. Rotor tip to distributor cap insert distance gapped too widely (worn cap or rotor) 3. High-resistance spark plug wire 4. Air-fuel mixture too lean (vacuum leak, broken valve spring, etc.) If the spark line is too long, possible causes include the following: 1. Fouled spark plug(s) 2. Spark plug(s) gapped too closely 3. Shorted spark plug or spark plug wire
plug wire, a spark plug gapped too far, or a lean fuel mixture affecting only those cylinders. A lean mixture (not enough fuel) requires a higher voltage to ignite because there are fewer droplets of fuel in the cylinder for the spark to use as “stepping stones” for the voltage to jump across. Therefore, a lean mixture is less conductive than a rich mixture.
READING THE SPARK LINES
Spark lines can easily be seen on either superimposed or raster (stacked) position. On the raster position, each individual spark line can be viewed. The spark lines should be level and one-fourth as high as the firing lines (1.5 to 2.5 kV, but usually less than 2 kV). The spark line voltage is called the burn kV. The length of the spark line is the critical factor for determining proper operation of the engine because it represents the spark duration time. There is only a limited amount of energy in an ignition coil. If most of the energy is used to ionize the air
Many scopes do not have a millisecond scale. Some scopes are labeled in degrees and/or percentage (%) of dwell. CHART 70–3 can be used to determine acceptable spark line length.
SPARK LINE SLOPE
Downward-sloping spark lines indicate that the voltage required to maintain the spark duration is decreasing during the firing of the spark plug. Although it is normal for the spark line to angle downward slightly, a steep slope indicates that the spark energy is finding ground through spark plug deposits (the plug is fouled) or other ignition problems. SEE FIGURE 70–46. An upward-sloping spark line usually indicates a mechanical engine problem. A defective piston ring or valve would tend to seal better in the increasing pressures of combustion. As the spark plug fires, the effective increase in pressures increases the voltage required to maintain the spark, and the height of the spark line rises during the duration of the spark. SEE FIGURE 70–47.
I G N I T I O N SYST E M D I AG N O SI S A N D S ERVIC E
809
20 KV
40 KV/V ROPE
15 KV
30 KV/V LENGTH OF ROPE REPRESENTS AMOUNT OF ENERGY STORED IN IGNITION COIL
10 KV
20 KV/V SAME LENGTH OF ROPE
5 KV
10 KV/V FIRING LINE
0 KV
0 KV/V
FIGURE 70–47 An upward-sloping spark line usually indicates a mechanical engine problem or a lean air-fuel mixture. SPARK LINE
An upward-sloping spark line can also indicate a lean air-fuel mixture. Typical causes include: 1. Clogged injector(s) 2. Vacuum leak
SAME LENGTH OF ROPE
FIRING LINE
3. Sticking intake valve
SEE FIGURE 70–48 for an example showing the relationship between the firing line and the spark line.
READING THE INTERMEDIATE SECTION
The intermediate section should have three or more oscillations (bumps) for a correctly operating ignition system. Because approximately 250 volts are in the primary ignition circuit when the spark stops flowing across the spark plugs, this voltage is reduced by about 75 volts per oscillation. Additional resistances in the primary circuit would decrease the number of oscillations. If there are fewer than three oscillations, possible problems include the following: 1. Shorted ignition coil 2. Loose or high-resistance primary connections on the ignition coil or primary ignition wiring
DWELL AND CURRENT-LIMITING HUMP
Ignition systems use a dwell period to charge the coil. Dwell is the time that current is charging the coil, and changes with increasing RPM in many electronic ignition systems. This change in dwell with RPM should be considered normal. Many EI systems also produce a “hump” in the dwell section, which reflects a current-limiting circuit in the control module. These current-limiting humps may have slightly different shapes depending on the exact module used. For example, the humps produced by various GM HEI modules differ slightly.
DWELL VARIATION (DISTRIBUTOR IGNITION) A worn distributor gear, worn camshaft gear, or other distributor problem may cause engine performance problems, because the signal created in the distributor will be affected by the inaccurate distributor operation. However, many electronic ignitions vary the length of the dwell period electronically in the module to maintain acceptable current flow levels through the ignition coil and ignition control module (ICM). Different EI systems use one of three different designs. The dwell length characteristic and the types of EI systems that use each design are as follows: 1. Dwell time remains constant as the engine speed is increased. 2. Dwell time decreases as the engine speed is increased. 3. Dwell time increases as the engine speed is increased.
810
CHAPTER 7 0
SAME LENGTH OF ROPE (ENERGY). IF HIGH VOLTAGE IS REQUIRED TO IONIZE SPARK PLUG CAP, LESS ENERGY IS AVAILABLE FOR SPARK DURATION. (A LEAN CYLINDER IS AN EXAMPLE OF WHERE HIGHER VOLTAGE IS REQUIRED TO FIRE WITH A SHORTER-THAN-NORMAL DURATION.)
SPARK LINE
IF LOW VOLTAGE IS REQUIRED TO FIRE THE SPARK PLUG (LOW FIRING LINE), MORE OF THE COIL’S ENERGY IS AVAILABLE TO PROVIDE A LONG-DURATION SPARK LINE. (A FOULED SPARK PLUG IS AN EXAMPLE OF LOW VOLTAGE TO FIRE, WITH A LONGER-THANNORMAL DURATION.)
FIGURE 70–48 The relationship between the height of the firing line and length of the spark line can be illustrated using a rope. Because energy cannot be destroyed, the stored energy in an ignition coil must dissipate totally, regardless of engine operating conditions.
NOTE: Waste-spark and coil-on-plug ignition systems also vary dwell time electronically within the PCM or ignition module.
ACCELERATION CHECK With the scope selector set on the display (parade) position, rapidly accelerate the engine (gear selector in park or neutral with the parking brake on). The results should be interpreted as follows: 1. All firing lines should rise evenly (not to exceed 75% of maximum coil output) for properly operating spark plugs. 2. If the firing lines on one or more cylinders fail to rise, this indicates fouled spark plugs.
ROTOR GAP VOLTAGE (DI SYSTEMS) The rotor gap voltage test measures the voltage required to jump the gap (0.03 to 0.05 in., or 0.8 to 1.3 mm) between the rotor and the inserts (segments) of the distributor cap. Select the display (parade) scope pattern and remove a spark plug wire (at the spark plug end), then using a jumper connected to a good ground, insert the jumper into the spark plug boot making sure it contacts the plug wire terminal. Start the engine and observe the height of the firing line for the cylinder being tested. Because the spark plug wire is connected directly to ground, the firing line height on the scope will indicate the voltage required to jump the air gap between the rotor and the distributor cap insert. The normal rotor gap voltage is 3 to 7 kV, and the voltage should not exceed 8 kV. If the rotor gap voltage indicated is near or above 8 kV, inspect and replace the distributor cap and/or rotor as required.
CYLINDER 1
POWER
KV 25